JPH04200593A - Clothes drier - Google Patents

Abstract

PURPOSE:To exactly detect clogging by providing a clogging detecting means for detecting the clogging of a filter and changing a prescribed value for detecting the clogging by an output of a temperature sensor of an inlet side. CONSTITUTION:The usual direr is constituted so that clogging is detected at the time when a temperature difference of an outlet and an inlet of a heater exceeds 130 deg, in the case when a heater inlet temperature, that is, an output of a second thermosensible element is 54 deg.C and the heater inlet temperature is 30 deg.C,, clogging is detected at a filter clogging state of 40%, even if the state is only at 20%. In the case of such a state, it is not said at all that clogging of the filter is detected exactly. Therefore, a clogging detection temperature difference is varied in accordance with a heater inlet temperature (t) as shown in the figure D. For instance, a temperature difference (y) of an inlet and an outlet of the heater is varied as (y)=-0.5t+150. When blinding of the filter is detected in such a way, the filter can detect clogging at about 30% irrespective of the inlet temperature of the heater.

Description

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

[Prior art] A device that detects filter clogging by measuring the temperature shown on the right as it passes through the heater and the temperature difference between the entrance and exit of the heater is
For example, it is disclosed in Japanese Patent Application Laid-Open No. 57-96699.

However, in these devices, if a semiconductor heater is used as the heater, even if the filter is in the same clogged state,
Due to the characteristics of the semiconductor heater, there is a problem in that the temperature difference between the heater inlet and outlet changes depending on the heater inlet temperature or the room temperature. That is, the semiconductor heater has a characteristic that the lower the temperature at the heater inlet, the greater the power output, and even in the same clogging state, the lower the heater inlet temperature, the greater the temperature difference between the heater inlet and outlet. Therefore, when the heater inlet temperature changes, there is a problem in that the accuracy of clogging detection varies.

Furthermore, even if it is attempted to detect filter clogging using only the heater outlet temperature, there is a problem in that when the heater inlet temperature decreases, the clogging detection sensitivity varies.

On the other hand, when performing dryness detection, even if the room temperature is the same, the power of the semiconductor heater will naturally differ depending on whether the filter is clogged or normal, so in order to accurately detect dryness, It is necessary to detect filter clogging with high accuracy.

[Problem to be solved by the invention]

The present invention was made in view of these conventional problems, and provides a clothes dryer that can accurately detect filter clogging even when the heater inlet temperature or room temperature changes, and can also accurately detect dryness. Its task is to provide.

[Means for Solving the Problems] A first aspect of the present invention is that a drum, a fan, and a motor for driving these are housed inside, and when the fan is driven, drying air drawn from the outside is sucked into the air. A clothes dryer in which the air enters the drum through a filter and a semiconductor heater at the rear of the mouth, and is discharged through a filter in front of the fan, wherein temperature sensors are installed at the inlet and outlet of the semiconductor heater, respectively. and detects whether the temperature difference between the two sensors has reached a predetermined value for clogging detection based on the outputs of the temperature sensor on the inlet side and the temperature sensor on the outlet side, and detects clogging of the filter. It is characterized in that it has a value means, and changes the predetermined value for the clogging test value based on the output of the temperature sensor on the inlet side.

Further, in a second aspect of the present invention, a drum, a fan, and a motor for driving these are housed inside, and when the fan is driven, drying air sucked from the outside is delivered to a filter and a semiconductor heater behind the air intake port. A clothes dryer in which the clothes dryer enters the drum through a filter and is discharged through a filter in front of the fan, wherein temperature sensors are provided at the outlet and inlet of the semiconductor heater and at the drum outlet, respectively;
Difference in output between temperature sensors at drum outlet and semiconductor heater inlet,
means for determining the time rate of change of the output difference between the temperature sensors at the semiconductor heater outlet and the semiconductor heater inlet, and the output difference between the temperature sensors at the drum inlet and the semiconductor heater inlet; means for determining the semiconductor heater inlet temperature; A calculation means for calculating the amount of laundry, material, clogging of the filter, and room temperature based on the outputs of the laundry, and a control means for controlling the operation based on the difference between the outputs of the temperature sensor on the drum outlet side and the temperature sensor on the inlet side of the semiconductor heater. , the control means has a table based on fuzzy inference for determining the output difference between the two sensors whose operation is to be stopped based on the calculation means, and the output difference is determined based on this table. .

[Function] According to the first invention, when the heater inlet temperature decreases, the temperature difference between the heater inlet and outlet is increased, and when the heater inlet temperature increases, the temperature difference is decreased, thereby preventing filter clogging. Accurate detection is possible regardless of the inlet temperature.

Further, according to the second invention, since the amount of laundry, material, filter clogging, and room temperature are estimated to determine the temperature difference between the drum outlet temperature and the heater inlet, dryness detection can be performed with high accuracy.

[Example] An embodiment of the present invention will be described below with reference to the drawings.

First, the structure of a clothes dryer to which the present invention is applied will be explained with reference to FIG.

FIG. 1 is a sectional view of a clothes dryer.

As shown in FIG. 1, 1 is a motor, and this motor 1
When rotates, the pulley 2, the drum 4 via the belt 3
rotates. 5 is an idler pulley, and this idler pulley 5 is for applying tension to the belt 3. Further, when the motor 1 rotates, a heat exchange type double-sided fan 8 simultaneously rotates via a fan pulley 6 and a round belt 7.

9 is a semiconductor motor, and when the double-sided fan 8 rotates, the hot air superheated by the semiconductor heater 9 enters the drum 4 through the ventilation hole 11 of the cylinder cover 10 and exchanges heat with the clothes in the drum 4, resulting in high temperature and high humidity. The air then passes through the filter cover 13, lint filter 14, partition plate 15, double-sided fan 8, and circulation duct 16 and returns to the semiconductor heater 9.
heated by.

On the other hand, as the double-sided fan 8 rotates, the cooling air is sucked into the machine through the air hole 18 of the rear cover 17, cools one side of the double-sided fan 8, and after cooling, the rear cover 1
The air is exhausted to the outside of the machine from the exhaust hole 20 at No.7.

Therefore, since the hot and humid air is cooled on the circulation side of the double-sided fan 8, the moisture contained in the clothes is condensed from steam and becomes water droplets. These water droplets are blown away by the double-sided fan 8 and discharged from the drain port 19 of the duct 16 to the outside of the machine.

31 is a first heat sensitive element, which is a temperature sensor H that measures the temperature of the air discharged from the drum 4.

32 is a second heat sensitive element, which is a temperature sensor L that measures the temperature of the air that passes through the heat exchange type double-sided fan 8 and before being reheated by the semiconductor heater 9.

33 is a third heat sensitive element, which is a temperature sensor P for measuring the temperature of the air reheated by the heater 9.

FIG. 2 is a block diagram showing a clothes dryer according to the present invention.

In FIG. 2, 24 is a microcomputer (hereinafter referred to as microcomputer) as a control circuit, and the microcomputer 24 controls each part. Analg signals from each of the heat-sensitive elements 31, 32, and 33 are input to this microcomputer, and clogging of the filter 14 is detected in accordance with this input. The microcomputer 24 is also provided with a program memory for storing programs, data tables, etc., and the microcomputer 24 controls each section according to the program written in the program scale.

Further, signals from an input key circuit 25 such as an operation switch are input to the microcomputer 24 .

From the microcomputer 24, there is a display section 26 that lights up LEDs, etc. to display each column, and a buzzer, etc., to sound a buzzer when an external key is inserted, when an abnormal condition occurs, etc. The signals are supplied to the notification section 27 consisting of the following.

Furthermore, the microcomputer 24 supplies control signals to a motor drive circuit 29 that drives the motor 1 and a semiconductor heater drive circuit 28, 28' that drives the semiconductor heater 9,9'. This is a graph showing the temperature difference between the entrance and exit. In addition, in the figure, A is when the clogging is 0%, B is when the clogging is 20%, and C is when the clogging is 40%.
The times are shown respectively.

For example, if the temperature difference between the heater inlet and outlet is 1, as in the conventional case,
Assuming that clogging is detected when the temperature exceeds 30deg, when the heater inlet temperature, that is, the output of the second heat-sensitive element 32 is 54°C, and the filter clogging state is 40%, the heater inlet temperature will be 30°C. In case of C, clogging is detected at 20%. This cannot be said to be accurate in detecting filter clogging.

Therefore, in the present invention, as shown in the figure, the clogging detection temperature difference is changed in accordance with the heater inlet temperature t. for example. Temperature difference y at heater inlet and outlet is y-0,5
It is changed as t+1.50.

By detecting filter clogging in this way, it becomes possible to detect when the filter is about 30% clogged regardless of the temperature when the heater is turned on.

In this embodiment, the heater inlet/outlet temperature difference is changed from the heater inlet temperature, but since the heater inlet temperature linearly corresponds to the room temperature, the heater inlet/outlet temperature may be changed in response to the room temperature.

Furthermore, the concept is exactly the same for a current detection method that uses a current transformer to detect filter clogging, and for a method in which the detected current value is changed depending on the heater inlet temperature (or room temperature).

FIG. 7 is a flowchart showing the operation of the first invention. Briefly, the temperatures at the heater inlet, outlet, and drum outlet are input to the microcomputer, and the temperature difference due to filter clogging is detected. If the filter is detected to be clogged before entering cooldown, a clogged message will be displayed and cooldown will begin.

Next, the second invention will be explained.

Examples of typical laundry items are shown in FIGS. 4 to 6. FIG. 4 shows the temperature curve under a towel load, FIG. 5 shows a temperature curve under a jeans load, and FIG. 6 shows a temperature curve under a mixed load of cotton and synthetic fibers.

When the filter (not shown) 4 is clogged, the temperature difference becomes smaller overall. On the other hand, when the room temperature is low, the temperature difference becomes large.

Here, A is the temperature difference between the drum outlet and the heater inlet, and is the value 10 minutes after the start of operation. Also, dT/dt is 10 at the start of operation.
5 minute temperature change from minute to 15 minutes.

As mentioned above, A, B, and C in FIG. 3 compare the relationship between the temperature difference between the heater outlet and inlet and the heater inlet temperature from filter clogging to normal operation.

Although this graph uses the heater inlet temperature as a parameter, there is a linear relationship between room temperature and heater inlet temperature, so there is no problem even if the temperature is changed to room temperature.

Now, this second invention allows the microcomputer to monitor the amount of laundry, material, filter clogging, and room temperature based on the output from each means.
4, and the microcomputer 24 controls the operation based on the difference between the outputs of the tram exit side temperature sensor 31 and the semiconductor heater entry side temperature sensor 32, and also determines the output difference between both sensors to stop operation based on the calculation result. The output difference is determined from a table based on fuzzy inference to perform control.

In the embodiment of this invention, fuzzy rules are defined as follows.

(a) When A is small, dT/dt is small, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, the temperature difference between the drum outlet and the heater inlet is increased.

(b) When A is small, dT/dt is small, the temperature difference between the heater outlet and inlet is large, and the heater inlet temperature is high, the temperature difference between the drum outlet and the heater inlet is made small.

(c) When A is large, dT/dt is large, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, the temperature difference between the drum outlet and the heater inlet is increased.

(d) If A is large, dT/dt is large, and the temperature difference between the heater outlet and inlet is large and the heater inlet temperature is high, the temperature difference between the drum outlet and the heater inlet is made small.

(e) If A is large, dT/dt is medium, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, increase the temperature difference between the drum outlet and the heater inlet.

(f) If A is large, dT/dt is medium, and the temperature difference between the heater outlet and inlet is large and the heater inlet temperature is high, reduce the temperature difference between the drum outlet and the heater inlet.

(g) If A is small, dT/dt is medium, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, increase the temperature difference between the drum outlet and the heater inlet.

(h) If A is small, dT/dt is medium, the temperature difference between the heater outlet and inlet is large, and the heater inlet temperature is high, reduce the temperature difference between the drum outlet and heater inlet.

(i) When A is small, dT/dt is small, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, the temperature difference between the drum outlet and the heater inlet is increased.

(j) When A is small, dT/dt is small, the temperature difference between the heater outlet and inlet is large, and the heater inlet temperature is high, the temperature difference between the drum outlet and the heater inlet is made small.

(k) When A is small, dT/d is large, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, the temperature difference between the drum outlet and the heater inlet is increased.

(1) When A is small, dT/dt is large, the temperature difference between the heater outlet and inlet is large, and the heater inlet temperature is high, the temperature difference between the drum outlet and the heater inlet is made small.

(m) If A is large, dT/dt is medium, the temperature difference between the heater outlet and inlet is small, and the heater inlet temperature is low, increase the temperature difference between the drum outlet and the heater inlet.

(n) When A is large, dT/dt is medium, the temperature difference between the heater outlet and inlet is large, and the heater inlet temperature is high, the temperature difference between the drum outlet and the heater inlet is made small.

According to the rules (a) to (n) above, the final temperature difference α is
It is determined using the Mamda Bi method (min-max centroid calculation method).

FIG. 8 is a flowchart of the second invention.
Temperature difference dT between drum outlet and heater inlet for 5 minutes after 5 minutes
/clt and calculate each temperature difference, then calculate the temperature difference α based on fuzzy rules.

Drying is terminated when the temperature difference between the drum outlet and the heater inlet becomes equal to or greater than α.

In this embodiment, filter clogging may be detected by a temperature sensor or by a count transformer.

Similarly, the determination of the heater inlet temperature may be handled by providing a new temperature sensor in the cooling intake section.

〔Effect of the invention〕

As explained above, according to the present invention, when the heater inlet temperature decreases, the temperature difference between the heater inlet and outlet is increased,
Conversely, when the temperature rises, the temperature difference is made small, so clogging of the fill can be accurately detected regardless of the heater inlet temperature.

Furthermore, since the amount of laundry, material, filter clogging, and room temperature are estimated to determine the temperature difference between the drum outlet temperature and the heater inlet, dryness detection can be performed with high accuracy.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing the structure of a clothes dryer to which the present invention is applied. FIG. 2 is a block diagram showing a clothes dryer according to the present invention. FIG. 3 is a characteristic diagram of the temperature difference between the heater inlet and the heater outlet. FIGS. 4 to 6 are characteristic diagrams showing the load characteristics of typical laundry items. FIG. 7 is a flowchart showing the operation of the first invention. FIG. 8 is a flowchart showing the operation of the second invention. 24... Microcomputer, 31... First heat-sensitive element, 32...
Second heat sensitive element, 33. Third heat sensitive element. Figure 1 Figure 4 Figure 5 Figure 7 Figure 8

Claims (2)

[Claims] (1) A drum, a fan, and a motor for driving these are housed inside, and when the fan is driven, drying air sucked in from the outside passes through a filter and a semiconductor heater behind the air intake port and enters the drum. The clothes dryer is equipped with temperature sensors at the inlet and outlet of the semiconductor heater, and the temperature sensor on the inlet side and the temperature sensor on the outlet side. It has a clogging detection means for detecting clogging of the filter by detecting whether the temperature difference between both sensors has reached a predetermined value for clogging detection from the output, A clothes dryer characterized in that a predetermined value for checking clogging is changed. (2) A drum, a fan, and a motor for driving these are housed inside, and when the fan is driven, drying air sucked in from the outside passes through a filter and a semiconductor heater behind the air intake port and enters the drum. A clothes dryer in which the clothes enter the machine, pass through a filter in front of the fan, and are discharged, the clothes dryer comprising: temperature sensors provided at the outlet and inlet of the semiconductor heater, and a drum outlet, respectively; and temperature sensors at the drum outlet and the semiconductor heater inlet. output difference,
means for determining the time rate of change of the output difference between the temperature sensors at the semiconductor heater outlet and the semiconductor heater inlet, and the output difference between the temperature sensors at the drum inlet and the semiconductor heater inlet; means for determining the semiconductor heater inlet temperature; a calculation means for calculating the amount of laundry, material, filter clogging, and room temperature based on the output of the laundry; and a control means for controlling the operation based on the difference between the outputs of the temperature sensor on the drum outlet side and the temperature sensor on the inlet side of the semiconductor heater. , the control means has a table based on fuzzy inference for determining the output difference between the two sensors whose operation is to be stopped based on the calculation means, and the output difference is determined based on this table. Clothes dryer.