DE102016220284A1 - DRYING DEVICE, CONTROL PROCESS AND CONTROL SYSTEM FOR THE DRYING DEVICE - Google Patents

Abstract

The present invention discloses a drying apparatus, a control method and a control system for the drying apparatus. The drying apparatus includes an air circulation system having a filtration device, a fan and a drum, and a coolant circulation system having a compressor with an adjustable rotational speed or speed, a liquefier, a throttling element and an evaporator. The controller controls the compressor according to the detection results of a first and a second temperature sensor to increase the heating speed and to reduce the energy waste, thus improving the efficiency of the drying apparatus.

Description

Cross-reference to related applications

This application claims the priority and benefit of Chinese patent application serial no. 201510680504.7 filed on 20 October 2015 with the State Patent Office of the People's Republic of China.

description

The present invention relates to a home appliance system, more particularly to a drying apparatus, a control method and a control system for the drying apparatus.

Currently existing drying devices include direct discharge type, condensation type and heat pump type drying devices. Compared to the other two types, the heat pump type drying apparatus has the features that it is relatively energy-saving, environmentally friendly, and the like. The heat pump system of the heat pump type drying apparatus includes a compressor, a condenser, a throttling element, and an evaporator. The blower is used to circulate the air to dry materials. After being subjected to heating in a high-temperature liquefier, the air is introduced into a drum to absorb the moisture of the materials, thereby becoming very humid air. The very humid air is then cooled and dehumidified by a low temperature condenser. The resulting condensed water is discharged from a drain configuration, and the low-temperature, low-humidity air obtained from the evaporator is introduced into a condenser for further heating. The resulting high temperature, low humidity air is introduced into the drum for further absorption. This procedure is continued in cycles until the moisture of materials in the drum meets the requirements. During the drying process, the temperature of the materials is getting higher and higher, and the moisture load in the materials is getting lower, the more condensed water is drained. If there is a slight change in energy in the coolant, the temperature of the air introduced into the drum, after being heated in the liquefaction, becomes higher during the drying process, which may affect the garments. The higher the temperature of the air introduced into the drum, the more moisture is absorbed by the air. However, some garments that are sensitive to the temperature prevailing in the drum are damaged due to the high temperature. Meanwhile, the air temperature through the evaporator becomes higher, the pressure and the temperature for the evaporation and the suction pressure and the temperature of the compressor become higher and higher, resulting in an increase of the aeration temperature and the aeration pressure.

A major investigative task is how to control the temperature of air introduced into the drum and the aeration temperature of the compressor during the drying process while conserving as much energy as possible during the heat pump dryer inspection. A current solution to the above problems is suggested by some manufacturers as being heat removal of a subcooler that is not included in the air circulating system of the dryer, in order to reduce the temperature of the air introduced into the drum, i. H. to control the heat energy introduced into the air circulation system. This scheme can better control the temperature of the air introduced into the drum during the drying process as well as the aeration temperature of the compressor, but has a waste of energy problem, i. H. it wastes the heat dissipated from the subcooler.

The object of the present invention is to provide a drying apparatus having an improved heat exchange efficiency, a control method and a control system for the drying apparatus.

This object is achieved by a drying apparatus according to claim 1, a process according to claim 11 and by a control system according to claim 14.

A drying apparatus includes an air circulating system, a coolant circulating system, a controller for controlling the drying apparatus, a first temperature sensor for detecting an air temperature at an air outlet of the condenser or an air inlet of a drum, and a second temperature sensor for detecting an air temperature at an air outlet of a compressor;
in which
the coolant recirculation system comprises the compressor with an adjustable rotational speed or frequency, a condenser, a throttling element and an evaporator, and
the air circulation system comprises a filtration device, a blower for supplying a driving force for air circulation to the air circulation system, and the drum for holding an object to be dried
and where
the evaporator is used for condensing and dehumidifying the air released from the drum and is located in an air passage behind an air outlet of the drum of the air circulation system,
the condenser is used for heating the dry air that has been dehumidified in the evaporator and is arranged in an air passage in front of the air inlet of the drum of the air circulation system, wherein the heated air is then introduced into the drum;
the controller is used to control a rotational speed or frequency of the compressor, and wherein
a drying operation of the drying apparatus has a heating stage and an isothermal stage, the rotational speed or frequency of the compressor with respect to the heating stage of the drying apparatus is greater than the rotational speed or frequency of the compressor with respect to the isothermal stage of the drying apparatus and the drying apparatus enters the isothermal stage after she has experienced rapid warming in the warming stage,
before the drying device enters the isothermal stage, the controller controls the rotational speed or frequency of the compressor in accordance with the air temperature at the air outlet of the condenser or at the air inlet of the drum obtained by the first temperature sensor,
after the drying device has entered the isothermal stage, controlling the rotational speed or frequency of the compressor in accordance with the air temperature at the condenser air outlet or at the air inlet of the drum obtained by the first temperature sensor and the air temperature at the air outlet of the compressor , which is obtained by the second temperature sensor, controls to maintain the air temperature at the condenser air outlet or at the air inlet of the drum in a given range.

The control method for the drying apparatus of the present invention provides the following technical system.

A method of controlling the above-described drying apparatus comprises the following steps:
Controlling, on the part of the controller, the compressor, to turn on and run at the preset rotational speed when the drying operation is started, to control the drying apparatus to quickly heat the air in the air passage, and detecting and Obtaining the air temperature at the air outlet of the condenser or at the air inlet of the drum by the first temperature sensor,
Controlling, on the part of the controller in accordance with the obtained detection result of the first temperature sensor, the compressor to run at or below the preset rotational speed or frequency, the air temperature at the condenser air outlet or at the drum air inlet at a preset temperature range of the controller to keep,
Controlling, on the part of the controller according to the air temperature at the air outlet of the condenser or at the air inlet of the drum, which is obtained by the first temperature sensor, and / or the air temperature at the outlet of the compressor, which is obtained by the second temperature sensor of the compressor there going to run at a current rotational speed or frequency, or making a control thereof, the rotational speed or frequency of the compressor when the rotational speed or frequency of the compressor is lower than the preset rotational speed or frequency.

The control system of the present invention provides the following technical system.

A control system for controlling the drying apparatus includes the controller, which is connected to the compressor by a signal and used to send a switch-on instruction, a stop instruction and a regulation instruction to the compressor,
wherein the controller comprises a power supply module, a central processing module, a compressor regulation module having a driver control unit and a driver unit, and a system sensor having the first temperature sensor, the second temperature sensor, and the humidity sensor,
the power supply module is used to receive a high voltage external input current and convert it into a low voltage current and deliver it to the central processing module, a driver control unit and a driver unit,
the central processing module is used as a control center for controlling the drying apparatus to provide a control signal to the compressor to control compressor operation, and an input signal from an interface between man and machine or an input signal from an operating unit and / or a signal from the sensor receive,
the input signal from the man-machine interface or the input signal from the operation unit has a quick-drying mode, an energy-saving drying mode, or a full-circumference drying mode derived from or selected by the operating unit;
the sensor signal has a temperature parameter detected by the first temperature sensor and the second temperature sensor and a relative humidity parameter detected by the humidity sensor,
the central processing module is used to generate a compressor control signal based on a calculation according to the input signal and / or the sensor signal described above, send the compressor compressor control signal generated from the calculation to the driver control unit of the compressor regulation module, and information to record or store the current regulation of the compressor;
the driver control unit of the compressor regulation module is used to receive the regulation signal from the central processing module for controlling the compressor operation and to provide the regulation instruction satisfying the requirement of the above-described regulation signal to the drive unit and to give the central processing module feedback about the operation information of the compressor, and
the compressor control module drive unit receives the regulation instruction from the driver regulation unit and outputs the specific regulation instruction to the compressor so that the compressor executes the specific regulation instruction that includes a signal of running at the preset rotation speed or frequency, a signal of decreasing the rotation speed or frequency and a signal of running at the current rotational speed or frequency.

Compared with the prior art, the rotational speed or frequency of the compressor in the present invention is regulated according to the detected results of the first temperature sensor and the second temperature sensor. By controlling the regulation of the rotational speed or frequency of the compressor, the compressor can operate under various drying working conditions to improve the heating rate and the drying temperature of the isothermal stage, which is to be controlled to be in an appropriate range, thereby controlling the rotational speed or speed Frequency of the compressor is properly assigned in each stage, the energy consumption is reduced and the efficiency of the drying device is improved.

Preferred embodiments will be explained in more detail below with reference to the accompanying drawings. Show it:

1 a perspective schematic view of an embodiment of the drying device in the present invention;

2 a schematic view of the Kühlmittelumwälzsystems and the air circulation system of the drying device in 1 ;

3 a schematic view showing the change in the rotational speed of the compressor of the drying device in 1 Fig. 11 illustrates the fluctuation tendency of the rotational speed of the compressor in various drying modes during the drying process;

4 a schematic view of the change in the air temperature at the air inlet of the drum of the drying device in 1 wherein the tendency of the air temperature to fluctuate at the air inlet of the drum is illustrated in different drying modes during the drying process;

5 a schematic view of the control of the drying device, which illustrates the relationship between each module or each unit of the controller;

6 a flow chart illustrating the control of the drying device in 1 in a quick drying mode;

7 a flow chart illustrating the control of the drying device in 1 in a full-circumference drying mode; and

8th a flow chart illustrating the control of the drying device in 1 in an energy-saving drying mode.

Hereinafter, embodiments of the drying device 100 , the control method and the control system for the drying apparatus in combination with the accompanying drawings. 1 Fig. 10 is a schematic view of an embodiment of the drying apparatus taking a drum-type dryer as an example and showing the inner assembly near its bottom without the lower case and the drum. 2 Fig. 12 is a schematic view of the coolant circulation system and the air circulation system of the drying apparatus, showing the circulation route of air and coolant. The compressor, the condenser, the throttling element and the evaporator are through the connecting line 101 connected in series. 3 illustrates the regulation for the rotational speed or frequency of the compressor, taking the rotational speed of the compressor of the drying device during operation as an example. 4 Fig. 10 shows the tendency of the air temperature to fluctuate at the air inlet of the drum of the drying apparatus. 5 shows the relationship between the functional modules of the Control of the control system in the present embodiment. 6 to 8th In the present embodiment, the flowcharts of the control of the drying apparatus in the quick drying mode, the full-circumference drying mode, and the energy-saving drying mode are shown.

As in 1 to 2 is shown, the drying device 100 an air circulation system A and a coolant circulation system R, wherein the coolant circulation system R is a compressor 1 with an adjustable rotational speed or frequency, a condenser 2 , a throttling element 3 and an evaporator 4 having. An inverter compressor or a variable speed compressor may be used as the compressor of the embodiment. The rotational speed or frequency of the compressor may be adjusted according to the control instruction of the controller, thereby improving the degree of coincidence between compressor load and power consumption, reducing unnecessary power consumption, and controlling the drying temperature of the drying apparatus to be within a suitable range. The outlet of the compressor is connected directly or indirectly to an inlet of the condenser. The outlet of the condenser is connected via a line directly or indirectly to an interface of the throttling element. The opposite interface of the throttling element is directly or indirectly connected to the evaporator, and the outlet of the evaporator is connected directly or indirectly to the inlet of the compressor. The throttling element may be an electronic expansion valve or a thermal expansion valve or a capillary. The subcooler or heat removal fan is not included in the coolant recirculation system. The coolant circulation system R may also be referred to as a heat pump system. The air circulation system A has a drum 5 , a filtration device 6 , a fan 7 and a water pump (not shown) used for discharging water, the drum 5 is used to hold the object to be dried, the filtration device 6 in the air passage between the outlet of the drum 5 and the evaporator 4 is installed and the blower 7 providing the air circulation system with the driving force for air circulation. An electric motor 8th Can be installed to the blower 7 More specifically, it is installed in the air passage between the air inlet of the drum and the condenser or in the air passage between the air outlet of the drum and the evaporator. The evaporator 4 which is used to condense and dehumidify the drum-derived air is installed in the air passage behind the air outlet of the drum. The condenser 2 is installed in the air passage in front of the air inlet of the drum. The air of the air circulation system, before being introduced into the drum, passes through the condenser and undergoes heat exchange with the condenser coolant. The condenser 2 is used to heat the dehumidified dry air in the evaporator 4 is used, and the heated air is then introduced into the drum to provide heat energy for drying the garments in the drum.

The working process of the coolant circulation system R is as follows: drawing in a cooling gas having a low temperature and a low pressure by the inverter compressor 1 and converting the refrigerant gas into a gas having a high temperature and a high pressure, introducing the gas at a high temperature and a high pressure into the condenser 2 and cooling to a high temperature, high pressure coolant through the air, wherein the relatively low temperature simultaneously heats the air, then throttling the coolant through the capillary / expansion valve 3 to a two-phase liquid gas stream with a low temperature and low pressure and introduction into the evaporator 4 and forming a gas having a low temperature and low pressure by absorbing heat in the evaporator 4 , simultaneously cooling the air for heat exchange down the evaporator 4 and condensing the water vapor from the air to reduce the humidity. After sucking in the cooling gas from the evaporator 4 through the inverter compressor 1 the above step is repeated periodically.

The working process of the air circulating system A is approximately as follows: introduction of the high temperature and low humidity air contained in the condenser 2 was subjected to heating in the drum 5 and performing heat exchange with the garments in the drum 5 To form a gas with a high temperature and high humidity, by absorbing the moisture in the drum 5 clothes to be dried, removing lint by the filtration device 6 , Introducing into the evaporator 4 for condensation and dehumidification, heating the low temperature, low humidity air in the condenser 2 and introducing the high temperature, high humidity air into the drum 5 , The above step is repeated periodically to complete the drying process. The condensation from the evaporator 4 is drained by a water pump through the drain configuration.

The rotational speed or frequency of the compressor in the heating stage of the drying apparatus is described with reference to FIG 3 and 4 higher than that in the isothermal stage the drying device. The present embodiment uses the variable-speed compressor as an illustrative example. The drying process of the drying device 100 has a heating stage and an isothermal stage. In the embodiment, the heating stage is defined as a rapid air heating operation of the air circulating system described above, in which the compressor runs at a relatively high preset rotational speed to reduce the drying time. The isothermal stage is defined as the drying operation of articles such as garments in a suitable temperature range in which the rotational speed of the compressor can be reduced to regulate the air temperature at the air inlet of the drum, thereby reducing energy waste and damage to the article to be dried, which is due to the excessively high drying temperature is avoided.

With reference to 2 in combination with 5 to 8th is the drying device 100 with a controller 200 and a system sensor connected to the controller by a signal. The control 200 is used to control the rotational speed of the compressor 1 used. The rotational speed of the compressor with respect to the heating stage of the drying apparatus is higher than the rotational speed of the compressor with respect to the isothermal stage of the drying apparatus, and the drying apparatus enters the isothermal stage after passing the rapid heating stage. The system sensor has a first temperature sensor 201 , a second temperature sensor 202 and a humidity sensor 301 on. The first temperature sensor 201 is for detecting the air temperature T1 at the air outlet of the condenser 2 or at the air inlet of the drum 5 used. The second temperature sensor 202 is used to detect the air temperature T2 at the air outlet of the compressor. In detail, the first temperature sensor 201 in the air passage between the condenser 2 and the inlet of the drum 5 installed, for example, is the first temperature sensor 201 fixed in the inner wall of the air passage, and the second temperature sensor 202 is installed on the coolant line between the compressor and the condenser, for example, the second temperature sensor 202 attached to the outer wall of the coolant line in the outlet side of the compressor.

If a throttling element 3 is an electronic expansion valve, the drying device further comprises a third temperature sensor 203 which is arranged on a refrigerant line between an outlet line of the evaporator and an inlet line of the compressor and used for detecting an outlet temperature of the evaporator T3, and a fourth temperature sensor 204 On, which is arranged on an inlet line of the evaporator or a central part of an outer wall of the evaporator and is used to detect an inlet temperature of the evaporator T4, the controller 200 is used to calculate the actual superheat heat degree SH of the outlet of the evaporator according to a temperature difference ΔT, (ΔT = T3-T4) between the outlet temperature of the evaporator T3 obtained by the third temperature sensor and the inlet temperature of the evaporator T4 obtained by the fourth temperature sensor is used, and if the current superheat degree of heat SH is greater than a threshold value of the superheat degree of heat SHm provided to the controller, the throttling element is switched to a more open position to increase the refrigerant flow rate of the refrigerant system.

Before the drying device 100 enters the isothermal stage, the controller 200 for controlling the rotational speed of the compressor 201 according to the air temperature T1 at the air outlet of the condenser or at the air inlet the drum, passing through the first temperature sensor 201 is used. In detail, the controller 200 provided with a first preset temperature T, and when the air temperature T1 at the air outlet of the condenser or at the air inlet of the drum by the first temperature sensor 201 is detected, reaches the first preset temperature T, the drying device enters 100 in the isothermal stage, and the rotational speed of the compressor 1 is reduced by the controller. After the drying device 100 has entered the isothermal stage controls the controller 200 the rotational speed of the compressor 1 according to the air temperature T1 at the air outlet of the condenser or at the air inlet of the drum, which is detected by the first temperature sensor, and / or the air temperature T2 of the outlet of the compressor, which is detected by the second temperature sensor. More specifically, when the drying apparatus is in the isothermal stage, the controller determines 200 whether the air temperature at the air outlet of the condenser or at the air inlet of the drum T1, through the first temperature sensor 201 is detected, the first preset temperature T exceeds (for example, T ranges between 44 and 55 ° C or between 55 and 65 ° C or between 65 and 75 ° C), and the rotational speed of the compressor is reduced by the controller, if the Air temperature at the air outlet of the condenser or at the air inlet of the drum, which is detected by the first temperature sensor exceeds the first preset temperature. If the air temperature at the air outlet of the condenser or at the air inlet of the drum detected by the first temperature sensor is not higher than the first preset temperature, the control must 200 Determine if the air temperature of the outlet of the compressor exceeds the corresponding preset temperature. In detail, the controller 200 is provided with a second preset temperature T ', and if the air temperature T2 of the outlet of the compressor exceeds the second preset temperature T' (T 'is in the range between 80 and 110 ° C), the rotational speed of the compressor is controlled by the controller 200 reduced.

In the embodiment, the rotational speed of the compressor is controlled by the controller 200 the drying device decreases when one of the two by the first temperature sensor 201 or the second temperature sensor 202 detected temperature parameter is higher than the corresponding preset temperature, whereby the coming of the compressor coolant flow rate is reduced in accordance with the liquefied 2 the heat transferred to the air is correspondingly reduced and the air temperature at the air inlet of the drum 5 is lowered immediately. However, the air temperature at the air inlet of the drum may increase continuously during the drying process. The controller further determines whether the air temperature at the air inlet of the drum exceeds the preset temperature during heating, and when the air temperature at the air inlet of the drum reaches the preset temperature T, the rotational speed of the compressor is reduced by 1% to 10%, depending according to the difference between the air temperature at the air inlet of the drum and the preset temperature. The larger the difference between T1 and T, the larger the amount of regulation, provided that the air temperature at the air inlet of the drum falls back to the preset temperature range, so that the control of the air temperature at the air inlet of the drum is achieved, ie, the rotational speed of the compressor is higher in the heating stage than in the isothermal stage, where the air supply is relatively stable.

With reference to 3 and 4 For example, the operation of regulating the rotational speed or frequency of the compressor will be described with reference to the example of regulating the rotational speed or frequency of the compressor of the drying apparatus. The rotational speed or frequency of the compressor in the heating stage is higher than in the isothermal stage. More specifically, the drying apparatus has a plurality of kinds of operation modes, for example, the rapid drying mode, the energy-saving drying mode, and the full-circumferential drying mode, and the drying apparatus can operate in any mode. When the drying apparatus is running in the rapid drying mode, the rotational speed of the compressor in the heating stage is the maximum of the entire working process of the drying apparatus. Here, "the maximum" refers to the rotational speed of the compressor 1 to the allowable value under a certain operating condition preset in the system, or to the maximum at which the controller allows the compressor to run instead of the maximum that the compressor can achieve, and it may vary depending on the different Types of drying devices and vary according to the ambient temperature. More specifically, taking the heating stage of the drying apparatus as an example, the rotational speed of the compressor is higher in the full-circumference drying mode of the drying apparatus than in the energy-drying mode of the drying apparatus and lower than in the rapid-drying mode of the drying apparatus. The various drying modes have different preset rotational speeds, each of which is explained as follows:
The rotational speed of the compressor in the heating stage with respect to the rapid drying mode in which the drying apparatus is running is 100% -200% of the nominal revolution of the compressor;
the rotational speed of the compressor in the heating stage with respect to the energy-drying mode in which the drying apparatus is running is 50% -100% of the rated revolution of the compressor; and
the rotational speed of the compressor in the heating stage with respect to the full-circumference drying mode in which the drying apparatus is running is 100% -150% of the rated revolution of the compressor.

As described above, in the heating stage, when passing through the first temperature sensor occurs 201 detected temperature parameter T1 reaches the first preset temperature T of the control, the drying process in the isothermal stage, and the controller 200 takes a control to reduce the rotational speed of the compressor. The extent of this reduction varies in the different drying modes, each of which is described as follows:
When the drying apparatus is running in the rapid drying mode, the rotational speed of the compressor becomes 1 due to the influence of the controller 200 lowered to 70% -150% of the rated speed of the compressor. The air temperature at the air inlet of the drum is maintained in the range of the first preset temperature T (for example, T is optionally in a range of 65-75 ° C) by reducing the power consumption of the compressor.

When the drying apparatus is running in the energy-saving drying mode, the rotational speed of the compressor becomes 1 due to the influence of the controller 200 lowered to 20% -80% of the rated speed of the compressor. The air temperature at the air inlet of the drum is maintained in the range of the first preset temperature T (for example, T is optionally in a range of 45-55 ° C) by reducing the power consumption of the compressor.

When the drying apparatus is running in the full-circumferential drying mode, the rotational speed of the compressor becomes 1 due to the influence of the controller 200 lowered to 60% -120% of the rated speed of the compressor. The air temperature at the air inlet of the drum is maintained in the range of the first preset temperature T (eg, T is optionally in a range of 55-65 ° C) by reducing the power consumption of the compressor.

The control 200 the drying device further comprises a humidity sensor 301 located in the air passage between the air outlet of the drum and the evaporator and used for detecting a humidity at the air outlet of the drum and a relative humidity in an air passage in front of the evaporator. Taking as an example the full-circumference drying mode of the drying apparatus, when the drying apparatus is in the isothermal stage, the controller controls the rotational speed of the compressor according to the humidity at the air outlet of the drum or at the inlet of the evaporator detected by the humidity sensor becomes. The controller is provided with a pre-set humidity S. When the humidity S1 at the air outlet of the drum or at the air inlet of the evaporator is below the above-described preset humidity S, the rotational speed of the compressor is reduced to 30% -80% of the rated rotational speed of the compressor. The air temperature at the air inlet of the drum is further reduced by reducing the power consumption of the compressor, for example the air temperature at the air inlet of the drum is maintained in the range between 50 and 60 ° C, thereby shortening the drying time, saving energy and further energy consumption is lowered.

The dryer runs in the three drying modes as described above. If the air temperature during heating at the air outlet of the condenser or at the air inlet of the drum, which is detected by the first temperature sensor is not higher than the first preset temperature, the control must 200 determine whether the air temperature T2 at the condenser air outlet is the corresponding preset temperature, for example, the second preset temperature T '(for example, T' is 80-110 ° C), with which the controller 200 is provided, and if T2 exceeds T ', the rotational speed of the compressor will increase due to the action of the controller 200 reduced.

During the drying process of the drying device, the compressor 1 in the manner set forth above, whereby the power consumption of the compressor is relatively reduced, the heat loss of the compressor is reduced, and the air temperature at the air outlet of the condenser or at the air inlet of the drum is maintained in the preset range. Compared to the conventional compressor-off operation for avoiding supercharger superheat, the process for regulating the rotational speed of the compressor in the embodiment can have a prolonged drying time due to turning off the compressor and a shortened life of the compressor due to the frequent turning on and off of the compressor Compressor is due, avoid. On the other hand, in the present embodiment, the regulation of the rotational speed of the compressor is performed 1 in any of the rapid drying mode, the energy-saving drying mode, and the full-circumferential drying mode of the compressors, first at a relatively high rotational speed, and then decreasing the rotational speed to maintain the respective preset drying temperature. If the articles to be dried have the same load, weight and initial water content, then the compressor will run when the drying device 100 running in the fast drying mode, at a relatively high rotational speed of the entire pass-through process, and requires a short drying time; when the drying device 100 running in the energy-drying mode, the compressor runs at a relatively low rotational speed, has a relatively low power consumption, and requires a long drying time; and if the drying device 100 In the full-circumferential drying mode, the compressor runs in the energy-saving and time-saving mode such that the drying time in the energy-saving and time-saving mode is shorter than the drying time in the energy-drying drying mode and longer than the drying time in the rapid-drying mode. The quick drying mode may be suitable for the user who does not have much time, the energy-saving drying mode may be suitable for the user who has enough time, and the full-scale drying mode may be suitable for the user with relatively enough time. The drying device 100 controls the rotational speed of the compressor properly depending on the heat energy required for the selected drying mode, and further controls the air temperature at the air inlet of the drum in the preset range, thereby improving the heat exchange efficiency.

With reference to 5 can the controller 200 be used in the control system of the drying device. The controller is connected to the compressor by a signal and is used to send a turn-on instruction, a stop instruction, and a regulator instruction to the compressor. The controller has a power supply module 205 , a central processing module 206 , a compressor regulation module 207 and a system sensor.

The central processing module 206 as a control center for controlling the drying apparatus is used for receiving an input signal from the interface between human and machine or an input signal from the operating unit and / or a signal from the sensor. The central processing module 206 is used to provide a control signal to the compressor 1 to control the compressor operation by regulating the rotational speed or frequency of the compressor used. The process of regulating the rotational speed or frequency of the compressor will be described by way of example with reference to the regulation of the rotational speed of the compressor.

The system sensor has a first temperature sensor 201 , a second temperature sensor 202 , a third temperature sensor 203 , a fourth temperature sensor 204 and a humidity sensor 301 wherein the first temperature sensor is used to detect the air temperature at the air outlet of the condenser or at the air inlet of the drum and to input the temperature parameter into the central processing module; the second temperature sensor 202 is used to detect the air temperature at the air outlet of the compressor and to enter the temperature parameter in the central processing module.

The input signal from the interface between man and machine 209 or the input signal from the keypad, through the central processing module 206 is received has instructions of the quick drying mode, the energy-saving drying mode or the full-circumference drying mode, which originate from or are selected by the operating unit. The sensor signal has temperature parameters determined by the first temperature sensor 201 , the second temperature sensor 202 , the third temperature sensor 203 and the fourth temperature sensor 204 and a through the humidity sensor 301 recorded relative humidity parameters. Specifically, the central processing module generates 206 a compressor speed feedback control signal to maintain or reduce the actual speed of rotation of the compressor by the temperature parameter T1 determined by the first temperature sensor 201 is compared with the first preset temperature T of the controller (for example, T is in the range of 45-55 ° C or 55-65 ° C or 65-75 ° C); and / or by the second temperature sensor 202 detected temperature parameter T2 is compared with the second preset temperature T 'of the controller (for example, T' is in the range of 80-110 ° C). The central processing module 206 is used to generate the compressor control signal based on the input signal and / or the sensor signal to send the compressor control signal generated from the calculation to the driver control unit 2071 the compressor regulation mode and used for recording or storing information of a current regulation of the compressor.

The compressor regulation module 207 has a driver control unit 2071 , a driver unit 2072 and a power factor correction module 2073 on. The power supply module 205 is for receiving a high voltage outdoor input power, converting a portion of the high voltage outdoor input power to a low voltage power to the central processing module 206 , the driver control unit 2071 and the driver unit 2072 and to input another part of the high voltage external input current into the power factor correction module 2073 used.

The driver control unit 2071 the compressor regulation module is for receiving the regulation signal from the central processing module for controlling the compressor operation and for supplying the regulation instruction that satisfies the requirement of the above-described regulation signal to the driver unit 2072 as well as used to the central processing module 206 to give feedback on the operating information of the compressor. The driver unit 2072 the compressor regulation module is for receiving the regulation instruction from the driver regulation unit and outputting the regulation instruction to the compressor 1 is used so that the compressor executes the regulation instruction having a signal of running at the preset rotational speed or frequency, a signal of decreasing the rotational speed or frequency, or a signal of running at the current rotational speed or frequency. In detail, the regulation instruction has a signal of Running at the preset rotational speed, a signal of decreasing the rotational speed and a signal of running at the current rotational speed. The power factor correction module 2073 is used to improve the power factor and the efficiency of the electric motor. The stream is successively through a filter 2080 and a rectifier 2081 into the power factor correction module 2073 entered. The filter 2080 is for receiving the high voltage external input current and outputting an electrical signal to the rectifier 2081 used. The rectifier is for receiving the output signal from the filter and supplying it to the power factor correction module 2073 used. The power factor correction module is used to receive the output signal from the rectifier and supply it to the above-described driver unit 2072 is used, and the power factor correction module is provided with a power factor correction control chip 2061 provided for sending the corresponding control signal to the power factor correction module.

When the throttling element is the electronic expansion valve, the control connected to the throttling element by a circuit signal is used to output an opening degree control signal to the throttling element, and the control is provided with a threshold value of superheat degree of heat SHm. The third temperature sensor 203 is used for inputting the temperature parameter obtained at the outlet of the evaporator into the central processing module, and the fourth temperature sensor 204 is inputted to the central processing module for inputting the temperature parameter obtained at the inlet of the evaporator 206 used. The central processing module is used to calculate the current superheat degree SHm of the outlet of the evaporator according to the difference ΔT between the temperature at the outlet of the evaporator and the temperature at the inlet of the evaporator and to determine whether the current superheat degree SH is greater than the threshold value of the superheat degree of heat SHm preset in the controller, and output the control signal to switch the electronic expansion valve to a more open position, if so.

A low power load module 208 the controller 200 has a fan 7 , an electric motor 8th for driving the drum or the fan and a water pump for draining water. The low power load module 208 is by a signal to the central processing module 206 connected, namely by also a buffer 2083 and a low power driver 2084 are provided. The central processing module 206 is for outputting the corresponding control signal to the low power load module 208 to control the operation of the low power load module used.

The control 200 is used to control compressor operation. The regulation of the compressor operation can be achieved by controlling the rotational speed or frequency of the compressor. A method for controlling the drying apparatus will be described with reference to the example of the regulation of the rotational speed of the compressor as follows:
Taxes, on the part of the controller 200 , the compressor 1 to turn on and run at the preset rotational speed when the drying procedure is started, whereby the drying device 100 is directed to rapidly warm the air in the passage of air;
Taxes, on the part of the controller 200 , the rotational speed of the compressor 1 according to the air temperature at the air outlet of the condenser or at the air inlet of the drum T1 passing through the first temperature sensor 201 is obtained; more precisely, taxes, on the part of the controller 200 , the compressor 1 going to run at or below the preset rotational speed described above to maintain the air temperature at the condenser air outlet or at the air inlet of the drum in the range of the preset temperature; and subsequently
Taxes, on the part of the controller 200 according to the air temperature at the air outlet of the condenser or at the air inlet of the drum T1 passing through the first temperature sensor 201 is obtained, and / or the air temperature T2 at the air outlet of the compressor, through the second temperature sensor 202 is obtained, the compressor 1 going to run at or below the above-described rotational speed to maintain the air temperature at the condenser air outlet or at the air inlet of the drum in the range of the preset temperature.

Specifically, the controller is provided with the first preset temperature T. When the air temperature at the air outlet of the condenser or at the air inlet of the drum obtained by the first temperature sensor reaches the first preset temperature T, the drying device passes 100 into the isothermal stage, and the controller 200 controls the rotational speed of the compressor to be less than the corresponding preset rotational speed.

When the air temperature at the air outlet of the condenser or at the air inlet of the drum T1 reaches the preset temperature T, the drying device 100 in the isothermal Stage occurs and the current rotational speed of the compressor is so far lower than the preset rotational speed, determines the controller 200 Furthermore, whether the air temperature at the air outlet of the condenser or at the air inlet of the drum T1, by the first temperature sensor 201 is obtained, the first preset temperature T exceeds; if the air temperature at the condenser air outlet or at the air inlet of the drum obtained by the first temperature sensor exceeds the first preset temperature, the controller decreases 200 a control to reduce the current speed of rotation of the compressor. The control 200 is provided with the second preset temperature T '; When the air temperature at the outlet of the compressor obtained by the second temperature sensor exceeds the second preset temperature, the controller decreases 200 a control to reduce the current speed of rotation of the compressor.

Further, a humidity sensor 301 provided to detect the relative humidity at the air inlet of the drum and in the air passage in front of the evaporator. The control 200 is provided with the preset humidity and is used to control the rotational speed of the compressor in accordance with the humidity H1 at the air outlet of the drum or the air inlet of the evaporator, through the humidity sensor 301 is used. When the air humidity of the air outlet of the drum or the air inlet of the evaporator is lower than the preset humidity S, the rotational speed of the compressor becomes 1 reduced to lower the air temperature at the air inlet of the drum by reducing the power consumption of the compressor.

6 to 8th Fig. 10 are flowcharts showing the control of the rotational speed of the compressor of the drying apparatus in different drying modes. With reference to 6 For example, the method of controlling the drying apparatus in the rapid drying mode includes the steps of:
S1: Press the drying device ON / OFF switch 100 and switching on the heat pump system; more precisely, switching on the compressor 1 and the low-power load module that the blower 7 and the electric motor 8th having;
S2: Operate the compressor 1 at the preset rotational speed which is 100% -200% of the rated rotational speed; and go to S3;
S3: Determine, on the part of the controller 200 whether the air temperature at the air outlet of the condenser, through the first temperature sensor 201 is detected, for example, a thermocouple, the first preset temperature reaches T (for example, T is optionally in the range of 65-75 ° C); if so, go to S4; if not, go to S2;
S4: Making a control by the controller 200 Going to this, the rotational speed of the compressor 1 to reduce to 70% -150% of the nominal rotational speed (the extent of this reduction is 1% -10%); and go to S5;
S5: Determine, on the part of the controller 200 whether the air temperature T1 at the air outlet of the condenser, through the first temperature sensor 201 is higher than the first preset temperature T; if so, go to S4; if not, go to S6;
S6: Determine, on the part of the controller 200 whether the air temperature T2 of the outlet of the compressor, through the second temperature sensor 202 is higher than the second preset temperature T '(for example, T' is optionally in the range of 80-110 ° C); if so, go to S4; if not, go to S5;
S7: Ending the drying process when the humidity at the air outlet of the drum reaches the final preset humidity.

With reference to 7 For example, the method of controlling the drying apparatus in the full-circumference drying mode includes the steps of:
S01: Press the drying device ON / OFF switch 100 and switching on the heat pump system; more precisely, switching on the compressor 1 and the low-power load module that the blower 7 and the electric motor 8th having;
S02: operating the compressor 1 at the preset rotational speed which is 100% -150% of the rated rotational speed; and go to S03;
S03: Determine, on the part of the controller 200 whether the air temperature at the air outlet of the condenser, through the first temperature sensor 201 is detected, for example, a thermocouple, the first preset temperature T reached (for example, T is optionally in the range of 55-65 ° C); if so, go to S04; if not, go to S02;
S04: Making a control by the controller 200 Going to this, the rotational speed of the compressor 1 to reduce to 60% -120% of the rated rotational speed (the extent of this reduction is 1% -10%); and go to S05;
S05: Determine, on the part of the controller 200 whether the air temperature T1 at the air outlet of the condenser, through the first temperature sensor 201 is higher than the first preset temperature T (for example, T is optionally in the range of 55-65 ° C); if so, go to S04; if not, go to S06;
S06: Determine, on the part of the controller 200 whether the air temperature T2 of the outlet of the compressor, through the second temperature sensor 202 is higher than the second preset temperature T '(for example, T' is optionally in the range of 80-110 ° C); if so, go to S04; if not, go to S05;
S07: Determine, on the part of the controller 200 Whether the humidity at the air inlet of the drum and the relative humidity H in the air passage in front of the evaporator passing through the humidity sensor 301 is less than the preset humidity S; if so, go to S08; if not, go to S05;
S08: Making a control by the controller 200 Going to this, the rotational speed of the compressor 1 to reduce to 30% -80% of the nominal rotational speed (the extent of this reduction is 1% -10%); and go to S09;
S09: Determine, on the part of the controller 200 whether the air temperature at the air outlet of the condenser, through the first temperature sensor 201 is detected, the new preset temperature reaches T1 (for example, T1 is optionally in the range of 50-60 ° C); if so, go to S09 (the rotational speed of the compressor remains the same); if not, go to S08;
S010: Ending the drying process when the humidity at the air outlet of the drum reaches the final preset humidity.

With reference to 8th For example, the method of controlling the drying apparatus in the energy-drying drying mode includes the steps of:
S001: Press the drying device ON / OFF switch 100 and switching on the heat pump system; more precisely, switching on the compressor 1 and the low-power load module that the blower 7 and the electric motor 8th having;
S002: Operating the compressor 1 at the preset rotational speed, which is 50% -100% of the rated rotational speed; and go to S003;
S003: Determine, on the part of the controller 200 whether the air temperature at the air outlet of the condenser, through the first temperature sensor 201 is detected, for example, a thermocouple, the first preset temperature T reached (for example, T is optionally in the range of 45-55 ° C); if so, go to S004; if not, go to S002;
S004: Making a control by the controller 200 Going to this, the rotational speed of the compressor 1 to reduce to 20% -80% of the rated rotational speed (the extent of this reduction is 1% -10%); and go to S005;
S005: Determine, on the part of the controller 200 whether the air temperature T1 at the air outlet of the condenser, through the first temperature sensor 201 is higher than the first preset temperature T (for example, T is optionally in the range of 45-55 ° C); if so, go to S004; if not, go to S006;
S006: Determine, on the part of the controller 200 whether the air temperature T2 of the outlet of the compressor, through the second temperature sensor 202 is higher than the second preset temperature T '(for example, T' is optionally in the range of 80-110 ° C); if so, go to S004; if not, go to S005;
S007: Ending the drying process when the humidity at the air outlet of the drum reaches the final preset humidity.

The drying device 100 and the method of controlling the drying device 100 have several types of operation modes, such as the quick-drying mode, the energy-saving drying mode, and the full-scale drying mode. The dryer can run in any of the drying modes. The rotational speed of the compressor and the air temperature at the air inlet of the drum vary in the different stages of the various drying modes, thus saving drying time and reducing energy consumption.

It should be noted that the above embodiments have been described for purposes of illustration and not to limit the present invention, for example, the definition given for guidance, e.g. "Forward," "rear," "left," "right," "up," "down," and the like, although a detailed description has been made with respect to the present invention which relates to the embodiments described above. It will be apparent to those skilled in the art that various combinations, modifications and substitutions are possible. Within the scope of the appended claims of the invention are included any technical systems and their modifications without departing from the scope and spirit of the invention.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• CN 201510680504 [0001]

Claims (18)

Drying device ( 100 ), an air circulation system (A), a coolant circulation system (R), a control ( 200 ) for controlling the drying device, a first temperature sensor ( 201 ) for detecting an air temperature (T1) at an air outlet of the condenser ( 2 ) or at an air inlet of a drum ( 5 ) and a second temperature sensor ( 202 ) for detecting an air temperature (T2) at an air outlet of a compressor ( 1 wherein the coolant recirculation system controls the compressor at an adjustable rotational speed or frequency, a condenser ( 2 ), a throttling element ( 3 ) and an evaporator ( 4 ) and the air circulation system has a filtration device ( 6 ), a blower ( 7 ) for supplying a driving force for air circulation to the air circulating system and the drum for holding an object to be dried; and wherein the evaporator is disposed in an air passage behind an air outlet of the drum of the air circulating system and configured to condense and condense air released from the drum dehumidify the condenser disposed in an air passage in front of the air inlet of the drum of the air circulation system and configured to heat dry air that has been dehumidified in the evaporator, wherein the heated air is then introduced into the drum; the controller is configured to control a rotational speed or frequency of the compressor. Drying device ( 100 ) according to claim 1, wherein a drying operation of the drying apparatus comprises a heating stage and an isothermal stage, the rotational speed or frequency of the compressor ( 1 ) with respect to the heating stage of the drying apparatus is greater than the rotational speed or frequency of the compressor with respect to the isothermal stage of the drying apparatus and the drying apparatus enters the isothermal stage after undergoing rapid heating in the heating stage before the drying apparatus enters the isothermal stage , the control ( 200 ) the rotational speed or frequency of the compressor according to the air temperature (T1) at the air outlet of the condenser ( 2 ) or at the air inlet of the drum ( 5 ) detected by the first temperature sensor ( 201 ) is controlled, after the drying apparatus has entered the isothermal stage, the controller controls the rotational speed or frequency of the compressor according to the air temperature (T1) at the condenser air outlet or at the air inlet of the drum obtained by the first temperature sensor , and the air temperature (T2) at the air outlet of the compressor, which by the second temperature sensor ( 202 ) in order to maintain the air temperature at the condenser air outlet or at the air inlet of the drum within a given range. Drying device ( 100 ) according to claim 2, wherein the drying device runs in either a rapid drying mode, an energy-saving drying mode or a full-circumferential drying mode, when the drying device is running in the rapid-drying mode, the rotational speed or frequency of the compressor ( 1 ) in the heating stage, the maximum rotational speed or frequency of the compressor during an entire running operation of the drying apparatus, the rotational speed or frequency of the compressor in the heating stage with respect to the full-circumferential drying mode in which the drying apparatus is running, is higher than the rotational speed or frequency of the compressor with respect to the energy-saving drying mode in which the drying device is running and lower than the rotational speed or frequency of the compressor with respect to the rapid-drying mode in which the drying device is running, the throttling element ( 3 ) is a capillary or an electronic expansion valve or a thermal expansion valve. Drying device ( 100 ) according to claim 3, wherein the rotational speed or frequency of the compressor ( 1 ) according to a control signal of the controller ( 200 ), the compressor with adjustable rotational speed or frequency is an inverter compressor or a variable speed compressor, the rotational speed or frequency of the compressor with respect to the heating stage of the drying apparatus is greater than the rotational speed or frequency of the compressor during a basic drying operation; the controller is provided with a first preset temperature, and when the air temperature (T1) at the air outlet of the condenser ( 2 ) or at an air inlet of the drum ( 5 ) detected by the first temperature sensor ( 201 ) reaches the first preset temperature, the drying apparatus enters the isothermal stage, and the rotational speed or frequency of the compressor is reduced by the controller. Drying device ( 100 ) according to claim 4, wherein the first temperature sensor ( 201 ) in an air passage between the condenser ( 2 ) and an inlet of the drum ( 5 ), and when the drying device is in the isothermal stage, the controller is ( 200 configured to determine whether the air temperature (T1) at the air outlet of the condenser or at the air inlet of the drum that is detected by the first temperature sensor ( 201 ), which exceeds the first preset temperature, if the air temperature at the condenser air outlet or at the air inlet of the drum obtained by the first temperature sensor exceeds the first preset temperature, the rotational speed or frequency of the compressor is controlled by the controller ( 200 ) decreased. Drying device ( 100 ) according to claim 4 or 5, wherein the coolant circulation system (R) does not comprise a subcooler, the controller ( 200 ) is provided with a second preset temperature and the second temperature sensor ( 202 ) on a coolant line between the compressor ( 1 ) and the liquefier ( 2 ) is arranged, when the drying device is in the isothermal stage, the rotational speed or frequency of the compressor is reduced by the controller, if the air temperature (T2) at the air outlet of the compressor ( 1 ) obtained by the second temperature sensor exceeding the second preset temperature. Drying device ( 100 ) according to claim 6, wherein the rotational speed of the compressor ( 1 ) in the heating stage with respect to the rapid drying mode in which the drying apparatus is running is 100% -200% of the rated revolution of the compressor, the rotational speed of the compressor in the heating stage with respect to the energy-drying mode in which the drying apparatus is running is 50% -100% of the rated revolution of the compressor, and the rotational speed of the compressor in the heating stage with respect to the full-circumferential drying mode in which the drying apparatus is running is 150% -200% of the rated revolution of the compressor; when the articles to be dried have the same load type, weight and initial water content, the drying device running in the fast drying mode requires the shortest drying time, the drying device running in the energy-drying mode needs the longest drying time, and the drying device, running in the full-circumference drying mode requires a drying time shorter than the drying time of the drying apparatus running in the energy-drying mode and longer than the drying time of the drying apparatus running in the rapid-drying mode. Drying device ( 100 ) according to claim 6 or 7, further comprising a humidity sensor ( 301 ) in an air passage between the air outlet of the drum ( 5 ) and the evaporator ( 4 ) and is configured to sense humidity at the air outlet of the drum and relative humidity in an air passage in front of the evaporator, the controller ( 200 ) is provided with a preset humidity and the controller is configured to control the rotational speed or frequency of the compressor ( 1 ) in accordance with the humidity at the air outlet of the drum or at the air inlet of the evaporator, when the drying apparatus is running in the full-circumferential drying mode and reaches the isothermal stage, in the case where the humidity at the air outlet of the drum or at the air inlet the evaporator is lower than the preset humidity, the rotational speed or frequency of the compressor is reduced to lower the air temperature at the air inlet of the drum. Drying device ( 100 ) according to one of claims 6 to 8, further comprising: a third temperature sensor ( 203 ) connected to a coolant line between an outlet line of the evaporator ( 4 ) and an inlet line of the compressor ( 1 ) and is configured to detect an outlet temperature of the evaporator (T3), and a fourth temperature sensor ( 204 ) disposed on an inlet pipe of the evaporator or a central part of an outer wall of the evaporator and configured to detect an inlet temperature of the evaporator (T4), the controller ( 200 ) is configured to calculate a current superheat degree of heat of the outlet of the evaporator according to a temperature difference between the outlet temperature of the evaporator obtained by the third temperature sensor and the inlet temperature of the evaporator obtained by the fourth temperature sensor; in that the current superheat heat degree is higher than a threshold value of superheat heat degree provided to the controller, the electronic expansion valve as the throttling element ( 3 ) is switched to a more open position to increase the coolant flow rate of the coolant system, the throttling element is an electronic expansion valve. Drying device ( 100 ) according to one of claims 6 to 9, wherein in the air circulation system (A) the passage of air between the outlet of the drum ( 5 ) and the evaporator ( 4 ) with a filtration device ( 6 ), the passage of air through the condenser ( 2 ) to heat exchange with the coolant in the condenser and then extend into the drum, and the evaporator is configured to cool and dehumidify the air from the air outlet of the drum, and in the coolant recirculation system (R). the outlet of the compressor ( 1 ) is connected directly or indirectly to an inlet of the condenser, an outlet of the condenser via a line directly or indirectly with an interface of the throttling element ( 3 ), the opposite interface of the throttling element is directly or indirectly connected to the evaporator, and the outlet of the evaporator is directly or indirectly connected to the inlet of the compressor. Method for controlling the drying device ( 100 ) according to one of claims 1 to 10, comprising the following steps: controlling, by the controller ( 200 ), the compressor ( 1 ) to turn on and run at the preset rotational speed or frequency in the controller when the drying operation is started, to control the drying apparatus to quickly heat the air in the air passage, and to detect the air temperature at the air outlet of the liquefier ( 2 ) or at the air inlet of the drum ( 5 ) by the first temperature sensor ( 201 ), Controlling, on the part of the controller in accordance with the detection result of the first temperature sensor, the compressor to run at or below the preset rotational speed or frequency to the air temperature at the air outlet of the condenser or at the air inlet of the drum in a preset temperature range of the Control, on the part of the control according to the air temperature at the air outlet of the condenser or at the air inlet of the drum, which is obtained by the first temperature sensor, and / or the air temperature at the outlet of the compressor, through the second temperature sensor ( 202 ), the compressor being at the current rotational speed or frequency, or making a control thereof, the rotational speed or frequency of the compressor when the rotational speed or frequency of the compressor is lower than the preset rotational speed, or frequency to maintain the air temperature at the air outlet of the condenser or at the air inlet of the drum in the preset temperature range of the control. Method for controlling the drying device ( 100 ) according to claim 11, wherein the controller ( 200 ) is provided with the first preset temperature; when the air temperature (T1) at the air outlet of the condenser ( 2 ) or at the air inlet of the drum ( 5 ) detected by the first temperature sensor ( 201 ) reaches the first preset temperature, the drying device enters the isothermal stage, and the controller controls the rotational speed or frequency of the compressor ( 1 ) is lower than the corresponding preset rotational speed or frequency when the drying device enters the isothermal stage and the controller controls the rotational speed or frequency of the compressor to be lower than the corresponding preset rotational speed or speed. frequency, the controller determines whether the air temperature at the air outlet of the condenser or at the air inlet of the drum obtained by the first temperature sensor exceeds the first preset temperature; if the air temperature at the air outlet of the condenser or at the air inlet of the drum obtained by the first temperature sensor exceeds the first preset temperature, the controller makes a control to decrease the current speed or frequency of rotation of the compressor, and / or the controller is provided with the preset second temperature; when the air temperature at the outlet of the compressor, through the second temperature sensor ( 202 ), which exceeds the second preset temperature, the controller makes a control to decrease the current rotational speed or frequency of the compressor. Method for controlling the drying device ( 100 ) according to claim 11 or 12, wherein a humidity sensor ( 301 ) is provided to the relative humidity at the air outlet of the drum ( 5 ) or the air inlet in the air passage in front of the evaporator ( 4 ), and the controller ( 200 ) is configured with the preset humidity and is configured to adjust the rotational speed or frequency of the compressor ( 1 ) according to the humidity of the air outlet of the drum or the air inlet of the evaporator obtained by the humidity sensor, if the humidity of the air outlet of the drum or the air inlet of the evaporator is lower than the preset humidity, the rotation speed or frequency of the Reduces compressor to lower the air temperature at the air inlet of the drum. Control system for controlling the drying device ( 100 ) according to one of claims 1 to 13, which controls ( 200 ) connected to the compressor ( 1 ) is connected by a signal and is configured to send a power-up instruction, a halt instruction, and a regulation instruction to the compressor, the controller controlling a power supply module (12). 205 ), a central processing module ( 206 ), a compressor regulation module ( 207 ), which has a driver control unit ( 2071 ) and a driver unit ( 2072 ), and a system sensor having the first temperature sensor ( 201 ), the second temperature sensor ( 202 ) and the humidity sensor ( 301 ), the power supply module is configured to receive a high voltage outdoor input current and convert it into a low voltage current and supply it to the central processing module, a driver control unit and a driver unit, the central processing module is configured as a control center for controlling the drying apparatus to provide a control signal to provide the compressor to control compressor operation and to receive an input signal from an interface between man and machine or an input signal from a control unit and / or a signal from the sensor, the input signal from the human-machine interface or the input signal from the operating unit has instructions relating to the quick-drying mode, the energy-saving drying mode or the full-circumference drying mode originating from or selected by the operating unit, the sensor signal by the first temperature rsensor and the second temperature sensor detected temperature parameters and a detected by the moisture sensor relative humidity parameter, the central processing module is configured to generate the control signal for the compressor based on a calculation on the basis of the input signal and / or the sensor signal, the control signal for the compressor, generated from the calculation to send to the driver control unit of the compressor regulation module and to record or store information of a current regulation of the compressor; the driver control unit of the compressor regulation module is configured to receive the regulation signal from the central processing module for controlling the compressor operation and to provide the regulation instruction satisfying the requirement of the above-described regulation signal to provide the drive unit and to return the operation information of the compressor to the central processing module and the drive unit of the compressor regulation module is configured to receive a regulation instruction from the driver regulation unit and output the regulation instruction to the compressor so that the compressor executes the regulation instruction including a signal of running at the preset rotational speed or frequency, a signal of decreasing the rotational speed or frequency, and has a signal of running at the current rotational speed or frequency. A control system according to claim 14, wherein the compressor regulation module of the controller ( 200 ) a power factor correction module ( 2073 ) for improving the power factor and the efficiency of the motor, and the power factor correction module comprising: a filter ( 2080 ) configured to receive the high voltage external input current and provide an electrical signal to a rectifier ( 2081 ) issue; the rectifier configured to receive the output signal from the filter and provide the output signal to the power factor correction module, wherein the power factor correction module is configured to receive the output signal from the rectifier and output the drive unit ( 2072 ), and a power factor correction control chip ( 2061 ) configured to send the corresponding control signal to the power factor correction module. A control system according to claim 14 or 15, wherein the first temperature sensor ( 201 ) is configured to control the air temperature at the condenser air outlet ( 2 ) or at the air inlet of the drum ( 5 ) and record the temperature parameter in the central processing module ( 206 ) to enter; the second temperature sensor ( 202 ) is configured to control the air temperature at the air outlet of the compressor ( 1 ) and record the temperature parameter in the central processing module ( 206 ) to enter; the central processing module is configured to be controlled by the first temperature sensor ( 201 ) recorded temperature parameters with the in the control ( 200 ) preset first temperature and / or by the second temperature sensor ( 202 ) to compare the second preset temperature preset in the controller to produce the compressor control signal configured to maintain the actual rotational speed or frequency of the compressor or reduce the rotational speed or frequency of the compressor. A control system according to any one of claims 14 to 16, further comprising the third temperature sensor (16). 203 ) and the fourth temperature sensor ( 204 ), in which the by a circuit signal with the throttling element ( 3 ) connected control ( 200 ) is configured to output an opening degree control signal to the throttling element, and the control is provided with a threshold value of superheat degree of heat, and wherein the third temperature sensor is configured to read the obtained temperature parameter at the outlet of the evaporator ( 4 ) into the central processing module ( 206 ), the fourth temperature sensor is configured to input the obtained temperature parameter at the inlet of the evaporator into the central processing module, and the central processing module is configured to set the current superheat degree of heat of the outlet of the evaporator according to the difference between the temperature at the outlet of the evaporator and the evaporator Calculate the temperature at the inlet of the evaporator to determine whether the current superheat heat is higher than the threshold of the superheat set in the control, and output the control signal for switching the electronic expansion valve to a more open position to the electronic expansion valve, if the current Overheating heat level is higher than the threshold value of the superheated heat setting preset in the control. Control system according to one of Claims 14 to 17, in which the controller ( 200 ) a low power load module ( 208 ), which the blower ( 7 ), an electric motor ( 8th ) for driving the drum ( 5 ) and a water pump for discharging water, and the low power load module by a signal to the central processing module ( 206 ) by adding a buffer ( 2083 ) and a low power driver ( 2084 ), and the central processing module is configured to output the corresponding control signal to the low power load module to control the operation of the low power load module.

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