CN112343290A - Multifunctional automatic-rating temperature adjusting system for floor - Google Patents

Abstract

The invention belongs to the field of floor temperature control, relates to a temperature regulation technology, and particularly relates to a multifunctional automatic-grading floor temperature regulation system which comprises a processor, wherein the processor is in communication connection with a heating module, an applicability evaluation module, a fault analysis module, a control module, a user side and a storage module, the heating module is used for analyzing the heating temperature of a floor, the applicability evaluation module is used for evaluating the use efficiency of the floor, the fault analysis module is used for carrying out fault analysis on the floor, and the user side comprises a registration unit, a login unit, a display screen and a switch key. The invention can automatically adjust the temperature of the floor surface, and carries out integrated calculation on the initial temperature value of the floor surface, the indoor air temperature value and the outdoor air temperature value to obtain a target temperature value, and then sends the target temperature value to the control module, and the control module controls the electric appliance element to heat the floor after receiving the target temperature value.

Description

Multifunctional automatic-rating temperature adjusting system for floor

Technical Field

The invention belongs to the field of floor temperature control, relates to a temperature adjusting technology, and particularly relates to a multifunctional automatic-grading temperature adjusting system for floors.

Background

Floor, i.e. the surface layer of the floor or floor of a house. Made of wood or other material. There are many classifications of floors, classified by structure: solid wood floors, laminate wood floors, three-layer solid wood laminate floors, bamboo and wood floors, anti-corrosion floors, cork floors, and the most popular multi-layer solid wood laminate floors.

Current intelligent house floor generally all has the self-heating function, and the use of cooperation air conditioner, heating installation improves the travelling comfort of indoor life, but current floor does not possess the automatically regulated function to the temperature, does not divide the district to divide the rating simultaneously to the floor, can't find the fault location fast when local trouble appears in the floor, can only carry out troubleshooting or direct change to whole floor, and user experience is relatively poor.

Disclosure of Invention

The invention aims to provide a multifunctional automatic grading temperature regulating system for a floor;

the technical problems to be solved by the invention are as follows:

(1) how to provide a floor temperature adjusting system capable of automatically adjusting the temperature;

(2) how to provide a floor temperature conditioning system that can be rated in zones.

The purpose of the invention can be realized by the following technical scheme:

a multifunctional automatic-rating temperature regulation system for floors comprises a processor, wherein the processor is in communication connection with a heating module, an applicability evaluation module, a fault analysis module, a control module, a user side and a storage module, the heating module is used for analyzing the heating temperature of the floors, the applicability evaluation module is used for evaluating the use efficiency of the floors, the fault analysis module is used for analyzing the faults of the floors, and the user side comprises a registration unit, a login unit, a display screen and a switch key;

the process of analyzing the heating temperature of the floor by the heating module specifically comprises the following steps:

s1: obtaining a floor surface temperature value and an indoor air temperature value, marking the sum of the floor surface temperature value and the indoor air temperature value as an initial temperature CSw, obtaining an outdoor temperature value and marking the outdoor temperature value as a reference temperature value CKw;

s2: by the formula

Obtaining a target temperature value MBw, wherein α 1, α 2 and α 3 are all preset proportionality coefficients, sending the target temperature value MBw to the control module, the control module controlling the heating element of the floor to heat the floor temperature until the floor surface temperature value reaches the target temperature value MBw, the heating module sending a heating completion signal to the processor, and the heating module sending the target temperature value MBw to the storage module for storage.

Further, the specific process of the suitability evaluation module for evaluating the use efficiency of the floor comprises the following steps:

v1: dividing the floor surface into i areas, setting i equal to 1, 2, … … n, setting t time periods, and setting t equal to 1, 2, … … m, acquiring pressure values of the i area surfaces in real time, and marking the pressure values of the i area floor surfaces in each time period as YLit;

v2: obtaining the maximum pressure value and the minimum pressure value of the floor surface of each area in each time period, subtracting the minimum pressure value from the maximum pressure value to obtain the maximum pressure difference value of the floor area in the time period, marking the maximum pressure difference value of the area i in each time period as ZDi, summing the ZDi and averaging to obtain the average maximum pressure difference value ZDp in the time period;

v3: acquiring an average maximum pressure difference threshold ZDpmin through a storage module, and when ZDp is not more than ZDpmin, judging the time period as an invalid time period; when ZDp > ZDpmin, determining the period to be an active period;

v4: extracting all effective time periods, marking the set of all effective time periods as Ae, where e is 1, 2, … … u, and u is less than or equal to n, marking the maximum pressure difference value of each region in the e time periods as YCei, summing and averaging the YCei to obtain the average maximum pressure difference value YCp of each region in the effective time periods;

v5: acquiring pressure evaluation coefficients YCmin and YCmax through a storage module;

if YCp < YCmin, judging the applicability grade of the floor area to be low;

if YCmin is less than or equal to YCp and less than YCmax, the applicability grade of the floor area is judged to be a middle grade;

if YCmax is less than or equal to YCp, the applicability grade of the floor area is judged to be high grade;

and sending the serial numbers of all floor areas with low applicability levels to the storage module and a display screen of the user side.

Further, the specific process of the fault analysis module for fault analysis of the floor includes the following steps:

z1: acquiring a target temperature value MBw through a storage module, and acquiring an evaluation temperature value through a formula PGw ═ β × MBw, wherein β is a preset proportionality coefficient, and 0.85< β < 0.95;

z2: marking the temperature values of the floor surfaces of the i areas as WDi, and if WDi < PGw, judging that the corresponding area has a fault and the area does not meet the heating requirement;

z3: the number of the fault areas is marked as K, and if Kmin is less than K and less than Kmax, the service state of the floor is marked as a maintenance state;

if K is less than or equal to Kmin, judging that the use state of the floor is a normal state;

and if the K is more than or equal to Kmax, judging that the service state of the floor is a scrapped state.

Further, the registration unit is used for registering the user through registration information, wherein the registration information comprises the name, the sex, the age, the occupation and the mobile phone number of the user; the login unit enables a user to log in through login information, and the login information comprises a login account and a login password.

The invention has the beneficial effects that: the invention has the following beneficial effects:

1. the floor surface temperature can be automatically adjusted through the arranged heating module, the floor surface initial temperature value, the indoor air temperature value and the outdoor air temperature value are integrated and calculated to obtain a target temperature value, then the target temperature value is sent to the control module, the control module controls the electric appliance element to heat the floor after receiving the target temperature value until the floor surface temperature reaches the target temperature value, the calculation method of the target temperature value is scientific and reasonable, the floor can directly adjust the floor temperature according to the target temperature value, and the user experience is good;

2. the floor can be graded in different areas through the arranged applicability evaluation module, the data of invalid time periods are removed by acquiring the pressure difference received by the floor of each area, the maximum pressure difference value of each area of the valid time periods is extracted for evaluation, all the floor areas are graded into three applicability grades, and the applicability grades of the floor represent the activity of a user in the floor area, so that the heating efficiency of the floor can be adjusted according to the activity of the user in the floor area;

3. the heating efficiency of the floor can be analyzed by dividing the area through the set fault analysis module, whether the floor of each area breaks down is judged, the integral using state of the floor is obtained by carrying out integration analysis on the area of the broken floor, and a user can check the integral using state of the floor in which stage in real time, so that the floor is convenient to maintain and replace for the user.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic block diagram of the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, a multifunctional automatic-rating temperature regulation system for a floor includes a processor, the processor is communicatively connected with a heating module, an applicability evaluation module, a fault analysis module, a control module, a user side and a storage module, the heating module is used for analyzing the heating temperature of the floor, the applicability evaluation module is used for evaluating the use efficiency of the floor, the fault analysis module is used for analyzing the fault of the floor, and the user side includes a registration unit, a login unit, a display screen and a switch key;

the process of analyzing the heating temperature of the floor by the heating module specifically comprises the following steps:

s1: after a user presses a switch key to start a floor heating mode, a floor surface temperature value and an indoor air temperature value are obtained, the sum of the floor surface temperature value and the indoor air temperature value is marked as an initial temperature CSw, an outdoor temperature value is obtained, and the outdoor temperature value is marked as a reference temperature value CKw;

s2: by the formula

Obtaining a target temperature value MBw, wherein α 1, α 2 and α 3 are all preset proportionality coefficients, sending the target temperature value MBw to the control module, the control module controlling the heating element of the floor to heat the floor temperature until the floor surface temperature value reaches the target temperature value MBw, the heating module sending a heating completion signal to the processor, and the heating module sending the target temperature value MBw to the storage module for storage.

The specific process of the suitability evaluation module for evaluating the use efficiency of the floor comprises the following steps:

v1: dividing the floor surface into i areas, setting i equal to 1, 2, … … n, setting t time periods, and setting t equal to 1, 2, … … m, acquiring pressure values of the i area surfaces in real time, and marking the pressure values of the i area floor surfaces in each time period as YLit;

v2: obtaining the maximum pressure value and the minimum pressure value of the floor surface of each area in each time period, subtracting the minimum pressure value from the maximum pressure value to obtain the maximum pressure difference value of the floor area in the time period, marking the maximum pressure difference value of the area i in each time period as ZDi, summing the ZDi and averaging to obtain the average maximum pressure difference value ZDp in the time period;

v3: acquiring an average maximum pressure difference threshold ZDpmin through a storage module, and when ZDp is not more than ZDpmin, judging the time period as an invalid time period; when ZDp > ZDpmin, the time interval is judged to be an effective time interval, and since late-night users sleep and work time users are not at home, the time interval is judged to be an ineffective time interval and removed through analysis, and data analysis is performed only aiming at the effective time interval, so that the reasonability of data is ensured;

v4: extracting all effective time periods, marking the set of all effective time periods as Ae, where e is 1, 2, … … u, and u is less than or equal to n, marking the maximum pressure difference value of each region in the e time periods as YCei, summing and averaging the YCei to obtain the average maximum pressure difference value YCp of each region in the effective time periods;

v5: acquiring pressure evaluation coefficients YCmin and YCmax through a storage module;

if YCp is less than YCmin, the applicability grade of the floor area is judged to be low grade, and the low grade indicates that the activity of the user on the floor is low;

if YCmin is less than or equal to YCp and less than YCmax, the applicability grade of the floor area is judged to be a middle grade;

if YCmax is less than or equal to YCp, the applicability grade of the floor area is judged to be high grade;

and sending the serial numbers of all floor areas with low applicability levels to the storage module and a display screen of the user side.

The specific process of the fault analysis module for carrying out fault analysis on the floor comprises the following steps:

z1: acquiring a target temperature value MBw through a storage module, and acquiring an evaluation temperature value through a formula PGw ═ β × MBw, wherein β is a preset proportionality coefficient, and 0.85< β < 0.95;

z2: marking the temperature values of the floor surfaces of the i areas as WDi, and if WDi < PGw, judging that the corresponding area has a fault and the area does not meet the heating requirement;

z3: the number of the fault areas is marked as K, if Kmin is less than K and less than Kmax, the service state of the floor is marked as a maintenance state, and a fault analysis module sends a floor maintenance signal to a processor;

if K is less than or equal to Kmin, judging that the use state of the floor is a normal state;

if the K is larger than or equal to Kmax, the service state of the floor is judged to be a scrapped state, and the fault analysis module sends a floor scrapping signal to the processor.

The registration unit is used for registering the user through registration information, wherein the registration information comprises the name, the sex, the age, the occupation and the mobile phone number of the user; the login unit enables a user to log in through login information, and the login information comprises a login account and a login password.

A multifunctional automatic-grading temperature regulation system for floors comprises a heating module for automatically regulating the temperature of the surface of a floor, an initial temperature value of the surface of the floor, an indoor air temperature value and an outdoor air temperature value, a target temperature value is obtained and then sent to a control module, the control module receives the target temperature value and then controls an electric element to heat the floor until the temperature of the surface of the floor reaches the target temperature value, the calculation method of the target temperature value is scientific and reasonable, the floor can directly and automatically regulate the temperature of the floor according to the target temperature value, a suitability evaluation module is used for carrying out regional grading on the floor, pressure difference received by each regional floor is obtained, data of invalid time periods are simultaneously rejected, the maximum pressure difference value of each region in valid time periods is extracted for evaluation, and all the regions of the floor are classified into three suitability grades, the suitability rating of floor represents the activeness of user in the floor region to can adjust the heating efficiency on floor according to the activeness of user in the floor region, can draw regional heating efficiency on floor through the failure analysis module and carry out analysis, judge whether regional floor breaks down, and obtain the holistic user state of floor through carrying out the integration analysis to the trouble floor region, the user can find out in real time which stage the holistic user state of floor is in, make things convenient for the user to maintain, change the floor.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

The above formulas are all numerical values obtained by normalization processing, the formula is a formula obtained by acquiring a large amount of data and performing software simulation to obtain the latest real situation, and the preset parameters in the formula are set by the technical personnel in the field according to the actual situation.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (4)

1. The multifunctional automatic-rating temperature regulation system for the floor is characterized by comprising a processor, wherein the processor is in communication connection with a heating module, an applicability evaluation module, a fault analysis module, a control module, a user side and a storage module, the heating module is used for analyzing the heating temperature of the floor, the applicability evaluation module is used for evaluating the use efficiency of the floor, the fault analysis module is used for analyzing the faults of the floor, and the user side comprises a registration unit, a login unit, a display screen and a switch key;

the process of analyzing the heating temperature of the floor by the heating module specifically comprises the following steps:

s1: obtaining a floor surface temperature value and an indoor air temperature value, marking the sum of the floor surface temperature value and the indoor air temperature value as an initial temperature CSw, obtaining an outdoor temperature value and marking the outdoor temperature value as a reference temperature value CKw;

s2: by the formula

Obtaining a target temperature value MBw, wherein α 1, α 2 and α 3 are all preset proportionality coefficients, sending the target temperature value MBw to the control module, the control module controlling the heating element of the floor to heat the floor temperature until the floor surface temperature value reaches the target temperature value MBw, the heating module sending a heating completion signal to the processor, and the heating module sending the target temperature value MBw to the storage module for storage.

2. The multifunctional automatic rating temperature regulation system for floors as claimed in claim 1, wherein the specific process of the suitability evaluation module to evaluate the use efficiency of the floor comprises the following steps:

v1: dividing the floor surface into i areas, setting i equal to 1, 2, … … n, setting t time periods, and setting t equal to 1, 2, … … m, acquiring pressure values of the i area surfaces in real time, and marking the pressure values of the i area floor surfaces in each time period as YLit;

v2: obtaining the maximum pressure value and the minimum pressure value of the floor surface of each area in each time period, subtracting the minimum pressure value from the maximum pressure value to obtain the maximum pressure difference value of the floor area in the time period, marking the maximum pressure difference value of the area i in each time period as ZDi, summing the ZDi and averaging to obtain the average maximum pressure difference value ZDp in the time period;

v3: acquiring an average maximum pressure difference threshold ZDpmin through a storage module, and when ZDp is not more than ZDpmin, judging the time period as an invalid time period; when ZDp > ZDpmin, determining the period to be an active period;

v4: extracting all effective time periods, marking the set of all effective time periods as Ae, where e is 1, 2, … … u, and u is less than or equal to n, marking the maximum pressure difference value of each region in the e time periods as YCei, summing and averaging the YCei to obtain the average maximum pressure difference value YCp of each region in the effective time periods;

v5: acquiring pressure evaluation coefficients YCmin and YCmax through a storage module;

if YCp < YCmin, judging the applicability grade of the floor area to be low;

if YCmin is less than or equal to YCp and less than YCmax, the applicability grade of the floor area is judged to be a middle grade;

if YCmax is less than or equal to YCp, the applicability grade of the floor area is judged to be high grade;

and sending the serial numbers of all floor areas with low applicability levels to the storage module and a display screen of the user side.

3. The multifunctional automatic rating temperature regulation system for floors as claimed in claim 2, wherein the specific process of the fault analysis module to analyze the fault of the floor comprises the following steps:

z1: acquiring a target temperature value MBw through a storage module, and acquiring an evaluation temperature value through a formula PGw ═ β × MBw, wherein β is a preset proportionality coefficient, and 0.85< β < 0.95;

z2: marking the temperature values of the floor surfaces of the i areas as WDi, and if WDi < PGw, judging that the corresponding area has a fault and the area does not meet the heating requirement;

z3: the number of the fault areas is marked as K, and if Kmin is less than K and less than Kmax, the service state of the floor is marked as a maintenance state;

if K is less than or equal to Kmin, judging that the use state of the floor is a normal state;

and if the K is more than or equal to Kmax, judging that the service state of the floor is a scrapped state.

4. The multifunctional automatic rating temperature regulation system for floors as claimed in claim 1, wherein the registration unit is used for the user to register through registration information, the registration information comprises the user's name, sex, age, occupation and mobile phone number; the login unit enables a user to log in through login information, and the login information comprises a login account and a login password.

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