JPH03133500A - Clothing dryer - Google Patents

Abstract

PURPOSE:To set operating time corresponding to the volume of stuff to be dried without being affected by ambient temperature by controlling an operation by detecting the ambient temperature, calculating a certain value based on the above detection, and comparing the value with difference between temperature in specific two places. CONSTITUTION:A temperature sensor 18 is provided at the front side of a heat exchange fan 13 and the rear side of a rotary drum 14, and a temperature sensor 20 in a vent route 10 connecting the heat exchange fan 13 to a heater 17, and a temperature sensor 22 at the inlet part of a back plate 21 which forms a cover covering the back plane of a housing 11. A microcomputer 25 detects the difference c'' between detection temperature a'' by the temperature sensor 18 and detection temperature b'' by the temperature sensor 20 with a temperature difference detecting means 26, and calculates a reference value f(d) based on the ambient temperature (d) detected with the temperature sensor 22 with an arithmetic means 27. Also, the value f(d) is decreased as the ambient temperature (d) is increased. A prescribed operation for prescribed time ts, after it goes to c''>f(d) is performed with a comparison means 28, and after that, the operation is stopped.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a clothes dryer used in general households.

(Prior Art) FIG. 5 shows the configuration of a conventional clothes dryer, and FIGS. 6 to 10 are graphs showing the characteristics of the conventional clothes dryer. In FIG. 5, 51 is a housing, 52
is a motor, 53 is a heat exchange fan, 54 is a rotating drum, 5
5.56 is a belt, 57 is a heater, 58 is a first temperature sensor, 59 is a ventilation path, 60 is a second temperature sensor,
Reference numeral 61 denotes a drain port, and a motor 52 is provided at the upper part of the housing 51, and a drain port 61 is provided between the motor 52 and a heat exchange fan 53 provided on the back side of the housing 51 and a rotating drum 54 provided in front of the heat exchange fan 53. belt 55 each
．． 56 is stretched, and the heat exchange fan 53 and rotating drum 54 are rotated by driving the motor 52. Further, a heater 57 is provided on the front side of the housing 51, a first temperature sensor 58 is provided behind the rotating drum 54 in the direction of the heat exchange fan 53, and a ventilation path 59 connects the heat exchange fan 53 and the heater 57. A second temperature sensor 60 is provided inside. As the heat exchange fan 53 rotates, the heater 57
The heated hot air is introduced into the rotating drum 54, thereby heating and drying the items (clothing) accommodated in the rotating drum 54, and the heat exchange fan 53
The moisture in the cold air flowing to the rear side and the warm moist air on the front side becomes water droplets and flows out of the machine from the drain port 61, and the dry air flows through the heater 57 and returns to the rotating drum 5.
Arrow A in Figure 4 indicates the flow of circulating air, and arrow B indicates the flow of cooling air. FIG. 6 shows the temperature a detected by the first temperature sensor 58 and the temperature a detected by the second temperature sensor 60 when the rotary drum 54 is operated with an amount of material to be dried close to its rated capacity. This shows the change over time. 7th
C shown in the figure is the difference between temperature a and temperature S shown in FIG. 6, and increases as the drying progresses. FIG. 8 shows the rate of change P per unit time (1) of C in FIG. 7 after a predetermined time nntx has passed after the start of operation. Let t2 be the time when P becomes a predetermined value compared to □, P<K, and after time t2, the rate of change of C per unit time P and the predetermined value are 2.
At the time t when P>K, it is determined that the drying has been completed. In addition, setting the time to 2 is
This is to prevent the rate of change P before that time (at the start of operation) from being 2 or more, thereby preventing false detection. Next, FIG. 9 shows the temperature a' detected by the first temperature sensor 58 and the temperature detected by the second temperature sensor 60 when the rotating drum is operated with an extremely small amount of material to be dried than the rated capacity. temperature b'
shows the change over time. Since there is less material to be dried in the rotating drum 54, the temperature a' rises rapidly from the start of operation. 1st
Figure 0 shows the difference C' between temperatures a' and b' in Figure 9 above.
Q' also rises rapidly. If C' reaches a predetermined value and becomes larger than l within a predetermined time period after the start of the movement, it is determined that the amount of material to be dried is small. When the amount of material to be dried is small, it is difficult to detect dryness as shown in Figures 6 to 8.
6 was driving.

(ItJ M to be solved by the invention) However, in the above conventional configuration, c゛〉K shown in FIG.
Time t5, which is 3, tends to be delayed as the volume of the material to be dried increases. If the capacity of the material to be dried increases to a certain extent, C'>K will not hold within t4, that is,
The larger the capacity of the material to be dried, the longer the operating time. here.

Consider the case where the ambient temperature in which the main body is placed is low. Since the temperature of the cooling air B shown in FIG. 5 is low, C' shown in FIG. 10 rises more rapidly. That is, C
'> K, the time t becomes earlier and the driving time becomes shorter. In addition, even if the capacity of the material to be dried is large to some extent, C' will increase due to the low ambient temperature, and c' will increase within t4.
There was a problem in that there was a possibility that K3 would hold.

The present invention solves the above conventional problems,
The purpose is to detect that the volume of the material to be dried is small without being affected by the ambient temperature.

(Means for Solving the Problem) In order to achieve the above object, the present invention calculates a certain value based on the temperature from the third temperature sensor that detects the R ambient temperature, and combines this value with the first and third temperature sensors. The operation is controlled by comparing the temperature difference between the two temperature sensors.

(Function) Therefore, with the configuration of the present invention, the operating time can be set according to the capacity of the material to be dried without being affected by the ambient temperature.

(Embodiment) FIG. 1 shows a longitudinal section of a clothes dryer according to an embodiment of the present invention, and FIG. 2 shows a block configuration of a clothes dryer according to an embodiment of the present invention.

Further, FIGS. 3 and 4 show the characteristics of a clothes dryer according to an embodiment of the present invention. In FIGS. 1 and 2, 11 is a housing, 12 is a motor, and 13 is a housing.
is a heat exchange fan, and 14 is a rotating drum.

15 and 16 are belts, 17 is a heater, 18 is a first temperature sensor, 19 is a ventilation path, 20 is a second temperature sensor, 21 is a back plate, 22 is a third temperature sensor, and 23 is a drain port.

24 is a temperature detection means, 25 is a microcomputer, which includes a temperature difference detection means 26, a calculation means 27, and a comparison means 2.
It has 8 built-in. Reference numeral 29 denotes a control means, which includes a motor 12 provided in the upper part of the housing 11, and a motor 12, a heat exchange fan 13 provided on the back side of the housing 11, and a rotating drum 14 provided in front of the heat exchange fan 13. Belts 15 and 16 are stretched between the motors 1 and 1.
2 drives the heat exchange fan 13 and the rotating drum 14.
Rotate. Further, the housing 11 has a heater 17 arranged on the front side, and a rotating drum 1 in front of the heat exchange fan 13.
A first temperature sensor 18 is provided behind the heat exchange fan 13 and the heater 17, and a second temperature sensor 20 is provided in the ventilation path 19 connecting the heat exchange fan 13 and the heater 17.

A back plate 21 serves as a lid that closes the back side of the housing 11, and a third temperature sensor 22 is provided at the intake port of this back plate 21 to detect the ambient temperature. As the heat exchange fan 13 rotates, hot air heated through the heater 17 is introduced into the rotating drum 14, thereby heating and drying the items (clothes) accommodated in the rotating drum 14. The cool air flowing to the back side of the heat exchange fan 13 and the warm moist air from the front side are heat exchanged by the heat exchange fan 13, and the moisture in the warm moist air becomes water droplets and flows out of the machine from the drain port 23. However, dry air is introduced into the rotating drum 14 again via the heater 17. Arrow C indicates the flow of circulating air, and arrow C indicates the flow of cooling air. In FIG. 2, the temperature sensing means 24 is
The temperatures of the temperature sensor 18, the second temperature sensor 20, and the temperature sensor 22 of FIG. 3 are detected.

The microcomputer 25 is based on the temperature difference detection means 26 which detects the difference between the temperatures of the first and second temperature sensors 18 and 20 detected by the temperature detection means 24, and the temperature from the third temperature sensor 22. It includes a calculation means 27 for calculating a value, and a comparison means 28 for comparing the temperature difference detected by the temperature difference detection means 26 and the value calculated by the calculation means 27. The control means 29 controls the current to the motor 12 and the heater 17 in accordance with the control signal output from the microcomputer 25.

In the above configuration, the temperature is when the rotary drum 14 is operated with an amount of material to be dried close to its rated capacity.

The temperature difference, the temperature difference change rate over time, and the judgment operation are the same as those shown in FIGS. 6 to 8 described in the conventional example.

On the other hand, in the above configuration, the temperature a'' detected by the first temperature sensor 18 and the second
FIG. 3 shows the temporal change in the temperature b'' detected by the temperature sensor 20. FIG. 4 shows the difference c'' between a'' and b''. Since there is less material to be dried, c” increases rapidly. 3rd
Based on the ambient temperature d detected by the temperature sensor 22, the calculation means 27 calculates the basic value f(d). f
(d) is a value that decreases as the ambient temperature d increases. A predetermined period of time after the start of operation, within ``c'' becomes the standard value, f
If it is larger than (d), it is determined that the amount of material to be dried is small. When the amount of material to be dried is small, it is difficult to detect dryness as shown in FIGS. 6 to 8, so C> f (
d) From time t,', operation is performed for a predetermined time t6'. With this kind of control, when the ambient temperature is low, C'
'' becomes large, but f (d) becomes a small value. Conversely, when the ambient temperature is high, c '' becomes small, but f (d) becomes large. Therefore, regardless of whether the ambient temperature is high or low, the time t at which C″〉f (d) is reached, depending on the volume of the material to be dried,
will be almost the same. Therefore, the operating time is determined by the volume of the material to be dried, regardless of the ambient temperature.

(Effects of the Invention) As is clear from the above embodiments, the present invention enables automatic drying operation with higher accuracy because the operating time can be set according to the volume of the material to be dried without being affected by the ambient temperature. It has the effect of being able to

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of a clothes dryer according to an embodiment of the present invention, FIG. 2 is a block diagram of a clothes dryer according to an embodiment of the present invention, and FIGS. 3 and 4 are clothes dryers according to an embodiment of the present invention. FIG. 5 is a longitudinal sectional view of a conventional clothes dryer, and FIGS. 6 to 10 are graphs showing the characteristics of a conventional clothes dryer when a small amount of material to be dried is placed in the dryer. 11, 51...Housing, 12.52...Motor, 13.53...Heat exchange fan, 14.54...Rotating drum, 15.16.55.56...Belt, 17
．． 57... Heater, 18.58... First temperature sensor 19.59... Ventilation route, 20.60...
-Second temperature sensor 21...back plate, 22...third
Temperature sensor 23, 61... Drain port, 24... Humidity detection means, 25... Microcomputer, 26...
...Temperature difference detection means, 27...Calculation means, 28...
Comparison means, 29...control means.

Claims (1)

[Claims] A heater serving as a heat source, a motor serving as a driving source, a rotating drum that houses the material to be dried and rotates and stirs it, a fan that introduces hot air heated through the heater into the rotating drum, and a heat exchanger that separates moisture from the humid air that has passed through the material to be dried in the drum; a first temperature sensor attached to the inlet side of the heat exchanger; and a first temperature sensor attached to the outlet side of the heat exchanger. a second temperature sensor;
a third temperature sensor attached to the cooling air intake side of the heat exchanger; temperature detection means for detecting temperature from the first temperature sensor, second temperature sensor, and third temperature sensor; temperature difference detection means for detecting a temperature difference between the first temperature sensor and the second temperature sensor; a calculation means for calculating a certain value based on the temperature from the third temperature sensor; and the temperature difference and the calculation means. and a control means for controlling the heater and motor based on the information obtained by the comparison means, and the control means controls the temperature difference within a predetermined time after the start of operation. The clothes dryer is characterized in that if it is determined that the value is greater than the value obtained by the calculation means, the operation is stopped after a predetermined period of time.