CN115185318A

CN115185318A - Temperature control method, device, medium, controller and bathroom heater

Info

Publication number: CN115185318A
Application number: CN202210981999.7A
Authority: CN
Inventors: 刘纯; 白旭; 仲冠滨; 潘柏江
Original assignee: Midea Intelligent Lighting and Controls Technology Co Ltd
Current assignee: Midea Intelligent Lighting and Controls Technology Co Ltd
Priority date: 2022-08-16
Filing date: 2022-08-16
Publication date: 2022-10-14
Anticipated expiration: 2042-08-16
Also published as: CN115185318B

Abstract

The disclosure relates to a temperature control method, a device, a medium, a controller and a bath heater, wherein the method comprises the following steps: acquiring a target temperature; determining a temperature interval based on the target temperature and a preset temperature interval division rule; acquiring the real-time temperature of the environment; generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature and the temperature interval of the real-time temperature; the temperature control strategy at least comprises whether a heating system and a heating gear are started or not, and whether a cooling system and a cooling gear are started or not. The heating or cooling system is firstly determined to be started according to the relative size of the target temperature and the real-time temperature, then the heating or cooling gear is determined according to the temperature interval of the real-time temperature, the temperature control strategy is adjusted along with the dynamic change of the real-time temperature, the accurate control of the environment temperature is realized, the temperature can be kept constant, the comfort of a user is improved, the energy consumption can be reasonably controlled, and the energy-saving effect is achieved.

Description

Temperature control method, device, medium, controller and bathroom heater

Technical Field

The disclosure relates to the technical field of temperature control, and in particular relates to a temperature control method, a temperature control device, a temperature control medium, a temperature control controller and a bathroom heater.

Background

In the related art, a user does not feel cold when taking a bath in a cold winter by installing a heater in a bathroom to increase the temperature in the bathroom. The temperature of the existing heater is mostly unadjustable in the use process, the comfort of users with different body-sensing temperatures is ignored for rapidly reaching the target temperature of the bathroom space temperature, and the user experience is greatly influenced by too high or too low bathroom temperature. In addition, because the heating gear is always in the same gear to work in the using process, energy consumption waste is caused, and the use cost of a user is increased.

Disclosure of Invention

In order to solve the above technical problems or at least partially solve the above technical problems, the present disclosure provides a temperature control method, apparatus, medium, controller, and bathroom heater.

The present disclosure provides a method of temperature control, the method comprising:

acquiring a target temperature;

determining a temperature interval based on the target temperature and a preset temperature interval division rule;

acquiring the real-time temperature of the environment;

generating a temperature control strategy according to the relative size of the target temperature and the real-time temperature and the temperature interval of the real-time temperature; the temperature control strategy at least comprises whether a heating system and a heating gear are started or not, and whether a cooling system and a cooling gear are started or not.

Optionally, the temperature intervals include a first temperature interval, a second temperature interval, a third temperature interval, a fourth temperature interval, a fifth temperature interval, and a sixth temperature interval; the temperature interval division rule comprises:

the first temperature interval: (∞, T) ₀ -a]；

The second temperature interval: (T) ₀ -a，T ₀ +b]；

The third temperature interval: (T) ₀ +b，+∞)；

A fourth temperature interval: (T) ₀ +c，+∞)；

A fifth temperature interval: [ T ] ₀ +b，T ₀ +c]；

Sixth temperature interval: (T) ₀ +d，+∞)；

Wherein a is more than c and more than b is more than 0, d is more than c and more than b is more than 0; t is ₀ Represents the target temperature, a represents a first parameter, b represents a second parameter, c represents a third parameter, and d represents a fourth parameter.

Optionally, the generating a temperature control strategy according to the relative magnitude of the target temperature and the real-time temperature and the temperature interval where the real-time temperature is located includes:

comparing the real-time temperature to the target temperature;

if the real-time temperature is lower than the target temperature and the real-time temperature is within a first temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein a heating gear is a first heating gear;

when the real-time temperature rises to a second temperature interval, determining the temperature control strategy to comprise starting a heating system, wherein the heating gear is a second heating gear, and the starting time is a first time threshold;

after the first time threshold, judging whether the real-time temperature is increased to a third temperature interval; if the real-time temperature is increased to be within a third temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein a heating gear is a third heating gear;

judging whether the real-time temperature is increased to a fourth temperature interval, and if the real-time temperature is increased to the fourth temperature interval, determining that the temperature control strategy comprises the steps of closing a heating system and opening a cooling system, wherein a cooling gear is a first cooling gear;

when the real-time temperature is reduced to a third temperature interval, determining the temperature control strategy, including closing a cooling system;

when the real-time temperature is reduced to a fifth temperature interval, determining the temperature control strategy to comprise starting a heating system, wherein the heating gear is a third heating gear;

the first heating gear, the second heating gear and the third heating gear are sequenced from large to small according to the heating power, and the sequence is as follows: the first heating gear is larger than the second heating gear and larger than the third heating gear.

Optionally, the generating a temperature control strategy according to the relative magnitude of the target temperature and the real-time temperature and the temperature interval where the real-time temperature is located further includes:

and if the real-time temperature is smaller than the target temperature and the real-time temperature is within a second temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein the heating gear is a second heating gear, and the starting time is a first time threshold.

Optionally, the generating a temperature control strategy according to the relative magnitude of the target temperature and the real-time temperature, and the temperature interval where the real-time temperature is located, further includes:

after the first time threshold value, if the real-time temperature is not increased to be within a third temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein a heating gear is a first heating gear;

when the real-time temperature is increased to a third temperature interval, judging whether the real-time temperature is increased to a fourth temperature interval;

if the real-time temperature rises to a fourth temperature interval, determining that the temperature control strategy comprises the steps of closing a heating system and opening a cooling system, wherein the cooling gear is a first cooling gear; when the real-time temperature is reduced to a third temperature interval, determining the temperature control strategy comprises closing a cooling system; if the real-time temperature is within a fifth temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein a heating gear is a second heating gear;

and if the real-time temperature is not increased to the fourth temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein the heating gear is a second cooling gear.

Optionally, if the real-time temperature is within a fifth temperature interval, determining the temperature control strategy includes turning on a heating system, and after the heating gear is the second heating gear, and/or if the real-time temperature is not increased within a fourth temperature interval, determining the temperature control strategy includes turning on the heating system, and after the heating gear is the second cooling gear, the method further includes:

and if the real-time temperature is within a second temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein the heating gear is a first heating gear.

after a first time threshold value, the real-time temperature is increased to a third temperature interval but not increased to a fourth temperature interval, and whether the real-time temperature is within a fifth temperature interval or not is judged;

if the real-time temperature is within a fifth temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein a heating gear is a third heating gear;

and if the real-time temperature is not in a fifth temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein the heating gear is a second heating gear.

if the real-time temperature is greater than or equal to the target temperature, judging whether the real-time temperature is in a sixth temperature interval,

if the real-time temperature is in a sixth temperature interval, determining that the temperature control strategy comprises starting a cooling system, wherein a cooling gear is a first cooling gear;

if the real-time temperature is not in a sixth temperature interval, determining that the temperature control strategy comprises starting a cooling system, wherein a cooling gear is a second cooling gear;

when the real-time temperature is less than or equal to the target temperature, determining the temperature control strategy comprises closing a cooling system;

when the real-time temperature is in a third temperature interval, determining the temperature control strategy to comprise starting a cooling system, wherein a cooling gear is a first cooling gear;

the heat dissipation power of the first cooling gear is larger than that of the second cooling gear.

The present disclosure also provides a temperature control device, including:

the first acquisition module is used for acquiring a target temperature;

the first determining module is used for determining a temperature interval based on the target temperature and a preset temperature interval division rule;

the second acquisition module is used for acquiring the real-time temperature of the environment;

the second determining module is used for generating a temperature control strategy according to the relative size of the target temperature and the real-time temperature and the temperature interval of the real-time temperature; the temperature control strategy at least comprises whether a heating system and a heating gear are started or not, and whether a cooling system and a cooling gear are started or not.

The present disclosure also provides a computer-readable storage medium having stored thereon a computer program for execution by a processor to perform the steps of any of the methods described above.

The present disclosure also provides a controller, comprising: a memory and a processor;

the memory having stored thereon executable programs or instructions;

the processor executes the program or instructions to implement the steps of any of the methods described above.

The present disclosure also provides a super bath, including: the controller is provided.

Compared with the prior art, the technical scheme provided by the disclosure has the following advantages:

the present disclosure provides a temperature control method, a device, a medium, a controller and a bath heater, wherein the method comprises: acquiring a target temperature; determining a temperature interval based on the target temperature and a preset temperature interval division rule; acquiring the real-time temperature of the environment; generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature and the temperature interval of the real-time temperature; the temperature control strategy at least comprises whether a heating system and a heating gear are started or not, and whether a cooling system and a cooling gear are started or not. Firstly, determining whether a heating system or a cooling system is started according to the relative sizes of the target temperature and the real-time temperature, then determining a heating gear or a cooling gear according to the temperature interval of the real-time temperature, and adjusting a temperature control strategy along with the dynamic change of the real-time temperature, thereby realizing the accurate control of the environmental temperature, keeping the constant temperature of a bathroom and improving the comfort of a user; meanwhile, the gear is adjusted according to the temperature range of the real-time temperature, and the energy consumption can be reasonably controlled, so that the energy-saving effect is achieved.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and, together with the description, serve to explain the principles of the disclosure.

In order to more clearly illustrate the embodiments or technical solutions in the prior art of the present disclosure, the drawings used in the description of the embodiments or prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a schematic flow chart of a temperature control method according to an embodiment of the disclosure;

FIG. 2 is a schematic diagram of a temperature range division provided by an embodiment of the present disclosure;

FIG. 3 is a schematic flow chart of another temperature control method provided by the embodiments of the present disclosure;

fig. 4 is a schematic structural diagram of a temperature control device according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of a controller according to an embodiment of the present disclosure;

fig. 6 is a schematic structural view of a bathroom heater provided in the embodiment of the present disclosure;

fig. 7 is a schematic view of the whole bathroom heater shown in fig. 6.

Detailed Description

In order that the above objects, features and advantages of the present disclosure may be more clearly understood, aspects of the present disclosure will be further described below. It should be noted that, in the case of no conflict, the embodiments and features in the embodiments of the present disclosure may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure, but the present disclosure may be practiced otherwise than as described herein; it is to be understood that the embodiments disclosed in the specification are only a few embodiments of the present disclosure, and not all embodiments.

In order to solve the problems in the background art, the embodiment of the disclosure provides a temperature control method, a device, a medium, a controller and a bathroom heater, wherein in the method, a heating system or a cooling system is determined to be started according to the relative sizes of a target temperature and a real-time temperature, then a heating gear or a cooling gear is determined according to a temperature interval where the real-time temperature is located, and a temperature control strategy is adjusted along with the dynamic change of the real-time temperature, so that the accurate control of the environment temperature is realized, the temperature of a bathroom is kept constant, and the comfort of a user is improved; meanwhile, the gear is adjusted according to the temperature range of the real-time temperature, and energy consumption can be reasonably controlled, so that the energy-saving effect is achieved.

The following describes an exemplary temperature control method, device, medium, controller and bathroom heater according to the embodiments of the present disclosure with reference to fig. 1 to 7.

Fig. 1 is a schematic flow chart of a temperature control method according to an embodiment of the present disclosure. Referring to fig. 1, the method includes:

s101, acquiring a target temperature.

Wherein the target temperature T ₀ The temperature is set by the user according to the self requirement, namely the temperature which the user hopes the indoor environment to reach; obtaining a target temperature T ₀ The method comprises the following steps: user sets target temperature T through panel ₀ And the target temperature T is set ₀ Storing in a storage unit; or the last history data is acquired from the storage unit.

S102, determining a temperature interval based on the target temperature and a preset temperature interval division rule.

Wherein the target temperature T is obtained ₀ Then, according to the preset temperature interval division rule, the temperature range of each temperature interval can be determined.

S103, acquiring the real-time temperature of the environment.

Wherein the real-time temperature T ₁ The current temperature of the environment is judged according to the inlet air temperature detected by the temperature detection system; the temperature detection system can be configured as all temperature detection devices known to those skilled in the art, such as a temperature sensor and a heat-sensitive sensor, and is not limited herein.

And S104, generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature and the temperature interval of the real-time temperature.

Wherein, the temperature control system comprises a heating system and a cooling system. The heating system or the cooling system can be any device or equipment known to those skilled in the art that can heat or cool the ambient temperature, and is not limited herein. The temperature control strategy at least comprises whether a heating system and a heating gear are started or not, and whether a cooling system and a cooling gear are started or not; the heating power of different heating gears is different, and the heat dissipation power of different cooling gears is different.

In this embodiment, the heating system is a Positive Temperature Coefficient thermistor (PCT) heating system; the heating power of the PTC heating system is controlled by adopting the following modes: firstly, adopt the silicon controlled rectifier to form controllable rectifier circuit to realize the Pulse Width Modulation (PWM) waveform output of control PTC heating system, when the duty cycle of PWM waveform changes, PTC heating system's heating power changes. The PTC heating system comprises a plurality of independent PTC heaters, and the heating power of the PTC heaters is controlled by controlling the opening/closing states of the PTC heaters in different combination forms; for example, the PTC heating system includes 3 heaters whose on/off states can be independently controlled, and at least three combinations of different heating powers, i.e., at least three heating stages, can be formed by controlling the on/off states of three sets of heaters in different combinations.

The cooling system is set as a ventilation system, and can discharge indoor hot air and suck outdoor cold air to reduce indoor environment.

The temperature control system also comprises a blowing system, the air blown out by the blowing system is communicated with the heating system, the heating system heats the air, and the air circulation can be promoted by starting the blowing system. By presetting the corresponding association relation between the blowing wind speed of the blowing system and the heating gear of the heating system, after the heating gear of the heating system is determined, the corresponding blowing wind speed can be determined. For example, the heating system and the blowing system are turned on simultaneously, and the blowing wind speed of the blowing system is positively correlated with the heating power of the heating system, that is, the higher the heating power of the heating system is, the higher the blowing wind speed of the corresponding blowing system is. By controlling the opening/closing state or the wind speed of the air exchange system and the blowing system, different heat dissipation efficiencies are generated by the opening/closing state or the wind speed in different combination forms, and the heat dissipation efficiencies correspond to different cooling gears. For example, when the ventilation system and the blowing system are simultaneously started, the heat dissipation power is high, and the cooling gear is a first cooling gear; only the ventilation system is started, the blowing system is closed, the heat dissipation power is low, and the cooling gear is a second cooling gear; when the ventilation system is closed, only the blowing system is opened (at the moment, the heating system is also closed), and the real-time temperature T acquired by the temperature detection system ₁ Influenced by ambient temperature, at ambient temperature greater than target temperature T ₀ Time, real time temperature T ₁ Gradually increasing; at ambient temperature less than target temperature T ₀ Time, real time temperature T ₁ And gradually decreases. The blowing wind speed of the blowing system is controlled by adopting the following modes: firstly, a controllable rectifying circuit is formed by adopting silicon controlled rectifier, and the blowing wind speed is controlled by controlling the rotating speed of a blowing motor; the second method comprises the following steps: the motor of the blowing system adopts a direct current motor to control the rotating speed of the motor, thereby achieving the purpose of controlling the blowing wind speed.

The embodiment of the disclosure provides a temperature control method, which includes firstly determining whether to start a heating system or a cooling system according to the relative size of a target temperature and a real-time temperature, then determining a heating gear or a cooling gear according to a temperature interval where the real-time temperature is located, and adjusting a temperature control strategy along with the dynamic change of the real-time temperature, thereby realizing accurate control of the ambient temperature, keeping the temperature of a bathroom constant, and improving the comfort of a user; meanwhile, the gear is adjusted according to the temperature range of the real-time temperature, and energy consumption can be reasonably controlled, so that the energy-saving effect is achieved.

In one embodiment, as shown in fig. 2, a schematic diagram of temperature interval division is provided for the embodiment of the present disclosure. Referring to fig. 2, the temperature intervals include a first temperature interval, a second temperature interval, a third temperature interval, a fourth temperature interval, a fifth temperature interval, and a sixth temperature interval; the temperature interval division rule comprises the following steps: first temperature interval: (∞, T) ₀ -a](ii) a The second temperature interval: (T) ₀ -a，T ₀ +b](ii) a The third temperature interval: (T) ₀ + b, + ∞); a fourth temperature interval: (T) ₀ + c, + ∞); a fifth temperature interval: [ T ] ₀ +b，T ₀ +c](ii) a Sixth temperature interval: (T) ₀ +d，+∞)。

Wherein a is more than c and more than b is more than 0, d is more than c and more than b is more than 0; t is ₀ Represents the target temperature, a represents the first parameter, b represents the second parameter, c represents the third parameter, and d represents the fourth parameter. a. The setting of the four parameters b, c and d can be flexibly set according to the requirement of the temperature control method, for example, the stricter the temperature control requirement is, the smaller and closer the value of the setting of the four parameters is, and the setting is not limited herein.

In the six temperature intervals, a first temperature interval, a second temperature interval and a third temperature interval are sequentially continuous, the second temperature interval is between the first temperature interval and the third temperature interval, the temperature in the first temperature interval is lower than that in the second temperature interval, and the temperature in the second temperature interval is lower than that in the third temperature interval; the third temperature interval is a union of a fourth temperature interval and a fifth temperature interval, that is, the third temperature interval = the fourth temperature interval ═ fifth temperature interval, the fifth temperature interval belongs to a portion of the third temperature interval having a lower temperature, and the fourth temperature interval belongs to a portion of the third temperature interval having a higher temperature; the sixth temperature zone and the fourth temperature zone also have an overlapping region, and the fourth temperature zone includes the sixth temperature zone, that is, the sixth temperature zone belongs to the fourth temperature zone, and the sixth temperature zone belongs to a portion having a higher temperature in the fourth temperature zone.

It should be noted that, under the influence of factors such as the distance between the inlet and the outlet of the blowing system, the indoor area, and the air circulation rate, the real-time temperature acquired by the temperature detection system has an error with the actual temperature of the environment, and the real-time temperature is usually higher than the actual temperature, so the boundary between the second temperature interval and the third temperature interval (or the fifth temperature interval) is set as T ₀ + b, set to a value greater than the target temperature, and controlling the ambient temperature in a fifth temperature interval [ T ] in combination with a temperature control strategy ₀ +b，T ₀ +c]Inner, a temperature interval slightly higher than the target temperature, real-time temperature T ₁ With a target temperature T ₀ The temperature difference is smaller (b is less than or equal to c); in this way, the actual temperature of the indoor environment is closer to the target temperature T ₀ The comfort of the user is improved.

In an embodiment, as shown in fig. 3, a schematic flow chart of another temperature control method provided in the embodiment of the present disclosure is shown. Referring to fig. 3, the method includes:

s301, setting a target temperature T ₀ 。

The steps are the same as S101, please refer to the explanation at S101, and are not described herein again.

S302, determining a target range.

The step is the same as S102, please refer to the explanation at S102, which is not described herein again.

S303, acquiring real-time environment temperature T ₁ 。

The step is the same as S103, please refer to the explanation at S103, and the description thereof is omitted.

S104, generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature and the temperature interval where the real-time temperature is located, and the method comprises the following steps:

s304, judging whether T is satisfied ₁ ＜T ₀ 。

In particular, the real-time temperature T is measured ₁ And a target temperature T ₀ Comparing if the real-time temperature T ₁ Less than target temperature T ₀ If the ambient temperature is low, that is, if the determination result in S304 is yes, S305 is executed to further determine the real-time temperature T ₁ Whether within the first temperature interval.

S305、T ₁ Whether or not within the first temperature interval.

Wherein if the real-time temperature T ₁ In a first temperature interval, i.e. T ₁ ≤T ₀ A, at this time, the real-time temperature T ₁ Less than target temperature T ₀ And the temperature difference between the two is larger, the temperature difference is larger than or equal to the first parameter a, and heating treatment is needed, therefore, determining the temperature control strategy comprises: s306, starting a heating system, wherein the heating gear is a first heating gear, and the heating power of the first heating gear is highest, so that the ambient temperature is quickly increased.

S307、T ₁ Whether within the second temperature interval.

In this step, the real-time temperature T is measured with the heating system turned on ₁ Gradually increasing to a real-time temperature T ₁ When the temperature is increased to the second temperature range (i.e., the determination result in S307 is yes), the real-time temperature T is measured ₁ Closer to the target temperature T ₀ Determining a temperature control strategy comprises: s308, starting a heating system, wherein the heating gear is a second heating gear, and the starting time is a first time threshold; the heating gear is adjusted from the first heating gear to the second heating gear, the heating power of the heating system is correspondingly reduced, the ambient temperature is controlled to rise at a proper rising speed, and the energy consumption is favorably reduced. S309 is executed after the heating system operates in the second heating gear for the first time threshold value, and the real-time temperature T is further judged ₁ Whether to rise to within the third temperature interval.

It should be noted that the first time threshold may be flexibly set according to the requirement of the temperature control method, and may be preset by a designer or input autonomously by a user, for example, but not limited thereto.

S309、T ₁ Whether to rise to within the third temperature interval.

After the heating system operates at the second heating gear for the first time threshold, if the real-time temperature T is higher than the first time threshold, the heating system is started to operate at the second heating gear ₁ Is raisedTo the third temperature interval, at which the real-time temperature T ₁ Has exceeded the target temperature T ₀ And the heating power of the heating system needs to be further reduced, determining the temperature control strategy comprises: s310, starting a heating system, wherein the heating gear is a third heating gear, and the heating power of the third heating gear is smaller than that of the second heating gear.

S311、T ₁ Whether to rise to within the fourth temperature interval.

In this step, the real-time temperature T is measured when the heating system is operated at the third heating gear ₁ The temperature may continue to rise to the fourth temperature interval, resulting in an excessively high indoor temperature. If the real-time temperature T ₁ Increasing to a fourth temperature interval (T) ₀ + c, + ∞) of the real-time temperature T ₁ With a target temperature T ₀ Is large (the temperature difference is larger than the third parameter c), the real-time temperature T ₁ Too high, a cooling process is required, and therefore, determining a temperature control strategy includes: s312, the heating system is turned off, the cooling system is turned on, the cooling gear is the first cooling gear, namely, the heating system is turned off, and the ventilation system and the air outlet system are turned on simultaneously.

S313、T ₁ Whether it is reduced to the third temperature interval.

Wherein, with the start of the cooling system, the real-time temperature T ₁ Gradually decrease to a real-time temperature T ₁ When the temperature is reduced to the third temperature interval, namely the real-time environment temperature T ₁ Less than T ₀ + c, real-time ambient temperature T ₁ Reduced to the lower temperature part of the third temperature interval, the real-time ambient temperature T ₁ With a target temperature T ₀ The temperature difference between the two is small, and the determining the temperature control strategy comprises the following steps: s314, closing the cooling system; after the cooling system is turned off, since the temperature of the external environment is low (the real-time temperature T obtained for the first time in S303) ₁ May also represent the current ambient temperature), the real-time temperature T ₁ Will continue to decrease until the real-time temperature T ₁ When the temperature is reduced to the fifth temperature interval (namely S315' T) ₁ Yes in the determination of "within the fifth temperature interval"), at which time the real-time temperature T is present ₁ Near target temperature T ₀ Determining a temperature control strategyThe method comprises the following steps: and starting the heating system, wherein the heating gear is the third heating gear, namely returning to execute S310.

In this embodiment, the temperature control system includes a heating system, a cooling system, and a blowing system; the corresponding relation exists between the blowing wind speed of the blowing system and the heating gear of the heating system, and the blowing wind speed is positively correlated with the heating power of the heating gear: when the heating system operates at a first heating gear, the corresponding blowing wind speed is maximum; when the heating system operates at a third heating gear, the corresponding air blowing speed is minimum; when the heating system operates at a second heating gear, the corresponding blowing wind speed is centered; the corresponding relation between the blowing wind speed of the blowing system and the heating gear of the heating system is stored in the storage unit in advance, and the blowing wind speed of the blowing system can be determined after the heating gear is determined.

It should be noted that the heating gear of the heating system in the embodiment of the present disclosure includes the first heating gear, the second heating gear and the third heating gear by way of example only, but does not constitute a limitation on the temperature control method provided by the embodiment of the present disclosure. In other embodiments, the number of heating gears may be set according to the requirement of the temperature control method, and is not limited herein.

In one embodiment, as shown in fig. 3, the S104 "generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature, and the temperature interval in which the real-time temperature is located", further includes: if the real-time temperature T ₁ Less than target temperature T ₀ And real time temperature T ₁ Within the second temperature interval, determining the temperature control strategy comprises: s308, starting the heating system, wherein the heating gear is a second heating gear, and the starting time is a first time threshold.

If the determination result of S304 is negative, the real-time temperature T is continuously determined ₁ Whether it is within the first temperature interval, if the real-time temperature T ₁ Is not in the first temperature zone, i.e., the determination result of S305 is NOIn conjunction with FIG. 2, the real-time temperature T may be determined ₁ In the second temperature interval, the real-time temperature T at the moment ₁ Closer to the target temperature T ₀ Starting a second heating gear of the heating system, and working as a real-time temperature T to prevent the frequent switching of gears from influencing the user experience ₁ When the temperature is within the second temperature range, the second heating gear forcibly runs the first time threshold.

In one embodiment, as shown in fig. 3, the step S104 "generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature, and the temperature interval in which the real-time temperature is located", further includes:

and S316, starting a heating system, wherein the heating gear is a first heating gear.

Wherein, the real-time temperature T cannot be adjusted after the heating system operates at the second heating gear for the first time threshold value due to the reasons of overlarge indoor area and the like ₁ When the temperature is increased to the third temperature interval, that is, the determination result in S309 is no, it indicates that the increasing rate is small when the current environment heating system operates at the second heating gear, and it takes a long time to maintain the real-time temperature T ₁ Is raised to the target temperature T ₀ (ii) a For this case, determining the temperature control strategy includes: s316, starting the heating system, wherein the heating gear is the first heating gear, adjusting the heating gear from the second heating gear to the first heating gear, and improving the heating power of the heating system so as to quickly raise the ambient temperature; then, S317 is executed to determine the real-time temperature T ₁ Whether it is raised to within the third temperature interval.

S317、T ₁ Whether to rise to within the third temperature interval.

Wherein the temperature T to be real-time ₁ Increasing to a third temperature interval (T) ₀ + b, + ∞), that is, yes in S317, then S318 is executed to further determine the real-time temperature T ₁ Whether to increase to within the fourth temperature zone interior.

S318、T ₁ Whether to rise to within the fourth temperature interval.

Wherein if the real-time temperature T ₁ Increasing to a fourth temperature interval (T) ₀ + c, + ∞), that is, a yes determination in S318, which is true at this timeTime temperature T ₁ With a target temperature T ₀ The temperature difference value is large (the temperature difference value is larger than the third parameter c), the real-time temperature is too high, and the temperature reduction treatment is needed, so that the temperature control strategy is determined to comprise: s319, the heating system is closed, the cooling system is started, the cooling gear is the first cooling gear, namely the heating system is closed, and the ventilation system and the air outlet system are simultaneously started.

If real time temperature T ₁ The temperature is not increased to the fourth temperature interval, namely the judgment result of S318 is no, and the real-time temperature T is at the moment ₁ In the third temperature interval, the lower part of the temperature, i.e. the real-time temperature T ₁ In the fifth temperature interval, the real-time temperature T ₁ With a target temperature T ₀ If the temperature difference is small, determining a temperature control strategy includes: and S323, starting a heating system, wherein the heating gear is a second cooling gear.

S320、T ₁ Whether it is reduced to the third temperature interval.

Wherein, with the start of the cooling system, the real-time temperature T ₁ Gradually decrease to a real-time temperature T ₁ When the temperature is decreased to the third temperature interval, that is, the determination result of S320 is yes, at this time, the real-time environment temperature T ₁ Not in the fourth temperature interval, corresponding to the real-time environmental temperature T ₁ Less than T ₀ + c, real-time ambient temperature T ₁ Reduced to the lower temperature part of the third temperature interval, the real-time ambient temperature T ₁ With a target temperature T ₀ The temperature difference therebetween is small, and determining the temperature control strategy includes S321 "turn off the cooling system".

S322、T ₁ Whether it falls within a fifth temperature interval.

After the cooling system is turned off, the temperature of the external environment is low (the real-time temperature T acquired for the first time in S303) ₁ And may also represent ambient temperature), real-time temperature T ₁ Will continue to decrease until the real-time temperature T ₁ When the temperature is reduced to the fifth temperature interval, the temperature control strategy is determined to comprise the following steps: s323, the heating system is started, and the heating gear is the second heating gear.

And S323, starting a heating system, wherein the heating gear is a second heating gear.

Specifically, as explained in connection with S316, for the case of the indoor area being too large, when the heating system operates in the second heating gear, the corresponding temperature-rising rate is smaller, and based on this, if the heating system operates in the third heating gear, the heating power and the temperature-rising rate will be smaller, and there is a high possibility that the natural heat dissipation power of the environment is greater than the heating power of the heating system, and the real-time temperature T is the real-time temperature T ₁ Will not continue to rise, will drop on the contrary; the heating power of the first heating gear is maximum, so that the rapid rise can be realized, but the real-time temperature T is realized at the moment ₁ In a fifth temperature interval [ T ₀ +b，T ₀ +c]Inner, near target temperature T ₀ And is slightly greater than the target temperature T ₀ If the heating system operates at the first heating gear, the real-time temperature T1 can be rapidly increased to a fourth temperature range, so that the temperature is reduced and increased to be frequently switched, the use experience of a user is influenced, and energy consumption waste is caused; therefore, the heating range of the heating system is determined as the second heating range.

In one embodiment, as shown in fig. 3, after determining the temperature control strategy includes turning on the heating system after the heating gear is the second heating gear if the real-time temperature is within the fifth temperature interval, and/or after determining the temperature control strategy includes turning on the heating system after the heating gear is the second cooling gear if the real-time temperature is not increased to within the fourth temperature interval, that is, after S323, the method further includes:

S324、T ₁ whether or not within the second temperature interval.

As explained in connection with S316, in the current environment, the increasing rate of the heating system is smaller when the heating system operates at the second heating gear, and when the heat dissipation power is greater than the heating power, the real-time temperature T cannot be maintained when the heating system operates at the second heating gear ₁ Constant in the fifth temperature interval, real-time temperature T ₁ Will fall within the second temperature interval, therefore, the further determination of the real-time temperature T is added after S323 ₁ If the real-time temperature is within the second temperature interval, that is, the determination result of S324 is yes, determining that the temperature control strategy includes: s316, starting a heating system, wherein the heating gear is the first additionAnd a hot gear.

In one embodiment, as shown in fig. 3, "generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature, and the temperature interval in which the real-time temperature is located" further includes: the real-time temperature T of the heating system is after the first time threshold value is operated in the second heating gear ₁ Increasing to the third temperature interval but not increasing to the fourth temperature interval, that is, if the determination result in S311 is no, S325 is executed to further determine the real-time temperature T ₁ Whether or not within a fifth temperature interval.

S325、T ₁ Whether or not within a fifth temperature interval.

Wherein if the real-time temperature T ₁ In a fifth temperature interval T ₀ +b，T ₀ +c]Inner, then real time temperature T ₁ Near target temperature T ₀ And is greater than the target temperature T ₀ Then determining a temperature control strategy comprises: and (5) starting the heating system, wherein the heating gear is the third heating gear, namely returning to execute S310. If the real-time temperature T ₁ Not in the fifth temperature interval, i.e. the real-time temperature T ₁ Lower limit value T of temperature less than fifth temperature interval ₀ + b, real time temperature T ₁ Within the second temperature interval, determining the temperature control strategy comprises: and starting the heating system, wherein the heating gear is the second heating gear, namely returning to execute S308.

In one embodiment, as shown in fig. 3, "generating a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature, and the temperature interval in which the real-time temperature is located" further includes:

S326、T ₁ whether or not within the sixth temperature interval.

Wherein if the real-time temperature T ₁ Greater than or equal to the target temperature T ₀ That is, if the determination result in S304 is yes, the ambient temperature is high, and the real-time temperature T is further determined ₁ Whether it is in the sixth temperature interval, if the real-time temperature T is within the sixth temperature interval ₁ In the sixth temperature interval (T) ₀ + d, + ∞) real time temperature T ₁ If too high, then determining the temperature control strategy comprises: s327, starting the cooling system, wherein the cooling gear is the first cooling gear, namely simultaneously starting the ventilation system and blowingA wind system. If real time temperature T ₁ Not in the sixth temperature interval, i.e. T ₀ ≤T ₁ ≤T ₀ + d, then determining a temperature control strategy comprises: s328 turns on the cooling system, where the cooling gear is the second cooling gear, that is, only the ventilation system is turned on, and the heat dissipation power of the ventilation system is smaller than that of the first cooling gear.

And S327, starting a cooling system, wherein the cooling gear is a first cooling gear.

Wherein, with the start of the cooling system, the real-time temperature T ₁ Gradually decrease to a real-time temperature T ₁ Less than target temperature T ₀ If (i.e., whether or not S329' satisfies T ₁ ≤T ₀ "yes), determining a temperature control strategy comprises: and S330, closing the cooling system, namely closing the ventilation system, wherein the blowing system keeps on the opening state. Since the ambient temperature is higher than the target temperature T ₀ The real-time temperature T acquired by the temperature detection system after the ventilation system is closed ₁ The influence of the external environment gradually increases, so that S331 needs to be executed to further determine "T ₁ Whether or not within the third temperature interval ".

And S328, starting the cooling system, wherein the cooling gear is a second cooling gear.

Wherein, though the real-time temperature T at that time ₁ Greater than or equal to the target temperature T ₀ And if the temperature difference between the air exchange system and the air blowing system is smaller than the fourth parameter d, determining that the temperature control strategy is that only the air exchange system is started, and the heat dissipation efficiency is lower than that when the air exchange system and the air blowing system are started simultaneously. To be real-time temperature T ₁ Is reduced to less than or equal to the target temperature T ₀ Time (i.e., whether or not S329 "satisfies T ₁ ≤T ₀ "yes), S330 is performed to turn off the cooling system, i.e., turn off the ventilation system, and turn on only the blower system.

S331、T ₁ Whether within the third temperature interval.

Wherein, under the condition of higher ambient temperature, after the cooling system is closed, the real-time temperature T is ₁ Will gradually rise; to be real-time temperature T ₁ In a third temperature interval, determining a temperature control strategy comprises: is openedAnd (5) returning to execute S327 if the temperature reduction gear is the first temperature reduction gear.

The heat dissipation power of the first cooling gear is larger than that of the second cooling gear. In this embodiment, the control strategy corresponding to the first cooling gear is to simultaneously turn on the blowing system and the air exchange system, and the control strategy corresponding to the second cooling gear is to only turn on the air exchange system and turn off the blowing system.

It should be noted that any one of the temperature control methods provided by the embodiments of the present disclosure is applied to a heating device (for example, a bathroom heater), and after the heating device is started, an air blowing system is automatically started, and the air blowing system operates at a gear with a low air blowing speed; the heating equipment is closed, and after the heating system stops running and the blowing system continues to run for a preset second time threshold, the blowing system stops running; so set up, distribute away the waste heat that produces among the heating system.

Based on the same inventive concept, the embodiments of the present disclosure further provide a temperature control apparatus, which is used for performing any of the steps of the temperature control method, and has corresponding beneficial effects, and the same points can be understood with reference to the above description, and are not described in detail hereinafter.

In one embodiment, as shown in fig. 4, a temperature control device is also provided for embodiments of the present disclosure. Referring to fig. 4, the temperature control apparatus 400 includes: a first obtaining module 401, configured to obtain a target temperature; a first determining module 402, configured to determine a temperature interval based on a target temperature and a preset temperature interval division rule; a second obtaining module 403, configured to obtain a real-time temperature of the environment; a second determining module 404, configured to generate a temperature control strategy according to the relative sizes of the target temperature and the real-time temperature, and a temperature interval in which the real-time temperature is located; the temperature control strategy at least comprises whether a heating system and a heating gear are started or not, and whether a cooling system and a cooling gear are started or not.

The apparatus may be implemented in software and/or hardware and may be integrated on any processor or electronic device having computing capabilities. Reference may be made to the description of any method embodiment of the disclosure for content not explicitly described in the apparatus embodiments of the disclosure.

On the basis of the foregoing embodiment, as shown in fig. 5, a schematic structural diagram of a controller provided in an embodiment of the present disclosure is shown. Referring to fig. 5, the controller 500 includes: a memory 501 and a processor 502; the memory 501 has stored thereon executable programs or instructions; the processor 502 runs the program or the instructions to implement the steps of any one of the above methods, which has corresponding beneficial effects, and is not described herein again to avoid repeated description.

Processor 502 may be, among other things, a Central Processing Unit (CPU) or other form of processing unit having data processing capabilities and/or instruction execution capabilities, and may control other components in the computer to perform desired functions.

Memory 501 may include one or more computer program products that may include various forms of computer-readable storage media, such as volatile memory and/or non-volatile memory. Volatile memory can include, for example, random Access Memory (RAM), cache memory (cache), and/or the like. The non-volatile memory may include, for example, read Only Memory (ROM), a hard disk, flash memory, and the like. One or more computer program instructions may be stored on a computer-readable storage medium and executed by processor 502 to implement the method steps of the various embodiments of the present application described above and/or other desired functions.

In addition to the methods and apparatus described above, embodiments of the present application may also be a computer program product comprising computer program instructions that, when executed by a processor, cause the processor to perform the method steps of the various embodiments of the present application.

The computer program product may write program code for carrying out operations for embodiments of the present invention in any combination of one or more programming languages, including an object oriented programming language such as Java, C + + or the like and conventional procedural programming languages, such as the "C" programming language or similar programming languages. The program code may execute entirely on the user's computing device, partly on the user's device, as a stand-alone software package, partly on the user's computing device and partly on a remote computing device, or entirely on the remote computing device or server.

On the basis of the foregoing embodiments, the embodiments of the present disclosure further provide a computer-readable storage medium, on which a computer program or an instruction is stored, and when the computer program or the instruction is executed by the processor 502, the processor 502 is enabled to execute the method steps of the various embodiments of the present disclosure, so as to implement the steps of any one of the methods, which has corresponding beneficial effects, and in order to avoid repeated description, no further description is provided here.

The computer readable medium may be embodied in the controller; or may be separate and not assembled into the controller.

A computer-readable storage medium may employ any combination of one or more readable media. The readable medium may be a readable signal medium or a readable storage medium. A readable storage medium may include, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or a combination of any of the foregoing. More specific examples (a non-exhaustive list) of the readable storage medium include: an electrical connection having one or more wires, a portable disk, a hard disk, a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or flash memory), an optical fiber, a portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing.

On the basis of the above embodiments, as shown in fig. 6, fig. 6 is a schematic structural view of a bathroom heater provided in an embodiment of the present disclosure. Referring to fig. 6, the super bath 600 includes: the controller 500 described above; have corresponding beneficial effects, and are not described herein again to avoid repeated descriptions.

In other embodiments, the super bath 600 may further include other components known to those skilled in the art, such as a blower system, a heating system, and a ventilation system, which are not limited herein.

Exemplarily, as shown in FIG. 6 and FIG. 2Fig. 7 is a schematic view of the whole bathroom heater shown in fig. 6. Referring to fig. 6 and 7, the super bath 600 includes: a controller 500, a ventilation system 601, a blowing system 602, a PCT heating system 603, a panel 604, a temperature detection system 605 and a box 606; wherein, the ventilation system 601, the blowing system 602, the PTC heating system 603 and the controller 500 are disposed in the box 606; a ventilation air outlet 6011 of the ventilation system 601 is arranged at the bottom of the box 606; an air inlet 6023, an air outlet 6021 and an air guide strip 6022 of the blowing system 602 are arranged on the panel 604, and the air guide strip 6022 can swing left and right to control the air direction of the air blown out by the blowing system 602; in the normal use process, the panel 604 is arranged below the box 606, when the blowing system 602 in the super bath 600 is started, the wind wheel in the interior of the volute rotates to suck air into the interior of the volute from the air inlet 6023 and then blows out the air through the air outlet 6021; the blowing system 602 further includes: a motor, a wind wheel and a volute; the PTC heating system 603 is disposed at the lower side of the air outlet 6021 and connected to the volute of the blowing system 602, so that the air blown from the blowing system 602 is heated by the PTC heating system 603; the PTC heating system 603 comprises: a plurality of independent PTC heaters 6031. A temperature sensing system 605 is disposed within the panel 604 above the intake 6023 for sensing the real-time temperature T of the environment ₁ (ii) a The controller 500 is arranged inside the box 606 and used for controlling the operation of the whole bathroom heater; the controller 500 includes a PTC control part, a blowing control part, and a storage unit, and the PTC control part controls the switching of the switching state of the PTC heating system 603 by sending an electrical signal, thereby controlling the heating power of the PTC heating system 603; the blowing control part is connected with the motor through an electric signal so as to control the rotating speed of the blowing motor and change the blowing air quantity; the storage unit mainly stores: target temperature T ₀ Real time temperature T ₁ And temperature interval division rules, as well as programs or instructions that can implement any of the methods provided by the above embodiments.

It is noted that, in this document, relational terms such as "first" and "second," and the like, are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a," "8230," "8230," or "comprising" does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

The previous description is only for the purpose of describing particular embodiments of the present disclosure, so as to enable those skilled in the art to understand or implement the present disclosure. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the disclosure. Thus, the present disclosure is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A method of temperature control, the method comprising:

acquiring a target temperature;

acquiring the real-time temperature of the environment;

2. The method of claim 1, wherein the temperature intervals comprise a first temperature interval, a second temperature interval, a third temperature interval, a fourth temperature interval, a fifth temperature interval, and a sixth temperature interval; the temperature interval division rule comprises:

the first temperature interval: (∞, T) ₀ -a]；

The second temperature interval: (T) ₀ -a，T ₀ +b]；

The third temperature interval: (T) ₀ +b，+∞)；

A fourth temperature interval: (T) ₀ +c，+∞)；

A fifth temperature interval: [ T ] ₀ +b，T ₀ +c]；

Sixth temperature interval: (T) ₀ +d，+∞)；

3. The method of claim 2, wherein generating the temperature control strategy according to the relative magnitudes of the target temperature and the real-time temperature and the temperature interval in which the real-time temperature is located comprises:

comparing the real-time temperature to the target temperature;

after the first time threshold, judging whether the real-time temperature is increased to a third temperature interval; if the real-time temperature rises to a third temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein the heating gear is a third heating gear;

judging whether the real-time temperature rises to a fourth temperature interval, if so, determining that the temperature control strategy comprises the steps of closing a heating system and opening a cooling system, wherein the cooling gear is a first cooling gear;

when the real-time temperature is reduced to a third temperature interval, determining the temperature control strategy comprises closing a cooling system;

when the real-time temperature is reduced to a fifth temperature interval, determining the temperature control strategy to comprise starting a heating system, wherein a heating gear is a third heating gear;

4. The method of claim 3, wherein generating a temperature control strategy according to the relative magnitudes of the target temperature and the real-time temperature and the temperature interval in which the real-time temperature is located further comprises:

5. The method according to claim 3 or 4, wherein the generating a temperature control strategy according to the relative magnitude of the target temperature and the real-time temperature and the temperature interval in which the real-time temperature is located further comprises:

when the real-time temperature rises to a third temperature interval, judging whether the real-time temperature rises to a fourth temperature interval;

if the real-time temperature rises to a fourth temperature interval, determining that the temperature control strategy comprises closing a heating system and opening a cooling system, wherein a cooling gear is a first cooling gear; when the real-time temperature is reduced to a third temperature interval, determining the temperature control strategy, including closing a cooling system; if the real-time temperature is within a fifth temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein a heating gear is a second heating gear;

and if the real-time temperature is not increased to the fourth temperature interval, determining that the temperature control strategy comprises starting a heating system, wherein the heating gear is a second heating gear.

6. The method of claim 5, wherein determining the temperature control strategy comprises turning on a heating system after a heating gear is the second heating gear if the real-time temperature is within a fifth temperature interval, and/or wherein determining the temperature control strategy comprises turning on a heating system after a heating gear is the second heating gear if the real-time temperature is not increased within a fourth temperature interval, further comprising:

7. The method of claim 3, wherein generating a temperature control strategy according to the relative magnitudes of the target temperature and the real-time temperature and the temperature interval in which the real-time temperature is located further comprises:

after the first time threshold value, the real-time temperature is increased to a third temperature interval but not increased to a fourth temperature interval, and whether the real-time temperature is within a fifth temperature interval or not is judged;

8. The method of claim 3, wherein generating a temperature control strategy according to the relative magnitudes of the target temperature and the real-time temperature, and a temperature interval in which the real-time temperature is located, further comprises:

when the real-time temperature is less than or equal to the target temperature, determining the temperature control strategy, including closing a cooling system;

9. A temperature control apparatus, comprising:

the first acquisition module is used for acquiring a target temperature;

10. A computer-readable storage medium, on which a computer program is stored, which computer program is executable by a processor for carrying out the steps of the method according to any one of claims 1 to 8.

11. A controller, comprising: a memory and a processor;

the memory having stored thereon executable programs or instructions;

the processor executes the program or instructions to implement the steps of the method according to any one of claims 1 to 8.

12. A super bath, comprising: the controller of claim 11.