JP3303895B2 - Drying equipment for granular material - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for drying a granular material such as a plastic molding material or a pharmaceutical material (hereinafter simply referred to as a material) so as to always fall within an allowable moisture content range. About.

[0002]

2. Description of the Related Art For example, when the moisture content (also called moisture content) of a plastic molding material supplied to a molding machine is inappropriate, silver or bubbles are formed in the molded product, or the molecular weight decreases due to hydrolysis. This causes a decrease in physical properties such as a decrease in the strength of the molded article. Therefore, properly maintaining the moisture content of the molding material is the most important thing for maintaining the quality of the molded product. For this reason, the molding material is usually preliminarily dried by passing it through a hopper dryer or the like before being supplied to the molding machine.

[0003] In the preliminary drying by the hopper dryer, high-temperature air is added to the molding material in the drying hopper in addition to the theoretically calculated time and the safe time obtained from experience to obtain the optimum drying conditions. The supply is continued for a period of time, that is, the time required to dehumidify the water to the allowable moisture content or less, and drying is performed. In addition, although this hopper dryer has a temperature sensor, it does not include a humidity sensor (including a dew point meter; the same applies hereinafter) for measuring the moisture content and control means for controlling the moisture content based on the detection of the temperature sensor. Is customary. Therefore, in this case, the type of material,
Depending on other drying conditions such as a storage state and a filling amount in a drying hopper, the moisture content may be too low within an allowable moisture range and may be excessively high, or may be too high and remain in an undried state. In the case of the former over-dry state, the injection pressure of the molding machine becomes high, the molecules of the material become small, or the additives are scattered. In addition to such deterioration in the quality of the molded product, when the material is in an excessively dry state, the heating energy is wasted as much as unnecessary heating energy is consumed.
When the latter is in an undried state, the injection pressure of the molding machine is reduced and the injection work is accelerated, but this causes molding defects such as deterioration in physical properties as described above.

Japanese Patent Laid-Open Publication No. 4-500 discloses a method for solving the above disadvantages of the drying method using a hopper dryer.
Japanese Patent Application Laid-Open No. 5 (1999) -2005 discloses a device (method) for drying a plastic molding material.

[0005] Japanese Patent Application Laid-Open No. 4-5005 discloses a stirring tank for heating and drying a plastic molding material, a drying air supply device comprising a compressor, a dryer, a flow controller and the like, and an exhaust port near the stirring tank. , An exhaust path provided in the exhaust path, a temperature sensor and a humidity sensor provided in the exhaust path, and connected to the temperature sensor and the humidity sensor, and an absolute humidity (including a dew point, which should be understood in this specification). And a controller for controlling the plastic drying device and detecting that the absolute humidity of the air on the exhaust path has become equal to or less than a predetermined drying state, and automatically stops the drying operation of the plastic drying device. It was made.

[0006]

However, according to the above-mentioned Japanese Patent Application Laid-Open No. 4-5005, it is detected that the absolute humidity of the air on the exhaust path of the stirring tank has fallen below a predetermined dry state. Since the drying operation of the drying device is automatically stopped, the material is prevented from being over-dried. However, in the case of this conventional example, since the drying operation (for example, supply of hot air) is stopped when the predetermined absolute humidity is reached, the method is applied only to batch-type material drying, and the material is continuously dried. There is a drawback that it cannot be performed as a continuous drying type material drying in which drying is carried out while being supplied.

According to the present invention, the quality of products such as molded products is improved and energy is saved by preventing over-drying and undried-up conditions so that appropriate drying can be performed by optimal water management in the continuous drying method described above. Plan. In addition, it is possible to detect fluctuations in molding conditions such as injection pressure and temperature in the molding machine to which the dried material is supplied, to stabilize molding conditions, and to assure quality of molded products. The purpose of the present invention is to provide a product capable of controlling moisture.

[0008]

According to a first aspect of the present invention, there is provided a drying apparatus for a granular material, comprising: a drying hopper for containing a material to be dried; and a material in the drying hopper. An apparatus for drying a granular material, comprising: an air source for supplying hot air for drying; and a temperature sensor and a humidity sensor provided at appropriate locations from the air source to an exhaust path through an air supply path and a drying hopper. A level meter is provided which is capable of adjusting the filling amount of the material supplied into the drying hopper based on the detection value of the humidity sensor to move the level position of the material so as to obtain a target moisture content. It is characterized by having.

According to a second aspect of the present invention, there is provided an apparatus for drying a granular material, comprising: a drying hopper for containing a material to be dried; an air source for feeding hot air for drying the material into the drying hopper; A temperature and humidity sensor provided at an appropriate position from an air source to an exhaust path through an air supply path and a drying hopper, and a drying apparatus for a granular material including at least:
A level meter that adjusts a filling amount of the material supplied into the drying hopper based on a detection value of the humidity sensor to move a level position of the material so as to obtain a target moisture content; and An air volume adjusting means for adjusting the air volume of the hot air supplied into the hopper so as to obtain a target water content is provided. Here, as the air volume adjusting means, an air volume adjusting valve or an inverter may be used.

According to a third aspect of the present invention, the humidity sensor includes a first humidity sensor provided between an air source and a heating means, a second humidity sensor provided near a material outlet of a drying hopper, and
A third humidity sensor provided at least in the vicinity of an exhaust port of the drying hopper, wherein the absolute humidity detected by the first humidity sensor is subtracted from the absolute humidity detected by the second humidity sensor, and the drying hopper is determined based on the difference value. It is preferable to calculate the moisture content in the vicinity of the material outlet and to operate one or both of the level meter and the air volume adjusting means so that the calculated moisture content matches the target moisture content.

As described above, the absolute humidity detected by the first humidity sensor is subtracted from the absolute humidity detected by the second humidity sensor, and the moisture content in the vicinity of the material outlet of the drying hopper is calculated based on the difference value. Can be used as a substitute for a moisture meter. Therefore, the use of a commonly used moisture meter not only increases the size of the apparatus but also increases the cost, but according to the above configuration, the moisture of the material can be easily measured by simple and inexpensive means. In this case, one or both of the level meter and the air volume adjusting means are operated to control the water content to be appropriate so that the calculated water content matches the target water content.

In this specification, the first humidity sensor, the second humidity sensor,
The humidity sensor, the third humidity sensor, and other humidity sensors include a dew point meter.

As a humidity sensor, a first humidity sensor provided between an air source and a heating means, a second humidity sensor provided near a material outlet of a drying hopper, and
A third humidity sensor provided at least in the vicinity of the exhaust port of the drying hopper, wherein the absolute humidity detected by the first humidity sensor is subtracted from the absolute humidity detected by the third humidity sensor, and the drying hopper is determined based on the difference value. It is preferable to calculate the water content in the vicinity of the material outlet and to operate one or both of the level meter and the air volume adjusting means so that the calculated water content matches the target water content.

As described above, the absolute humidity detected by the first humidity sensor is subtracted from the absolute humidity detected by the third humidity sensor, and the water content near the exhaust port of the drying hopper is calculated based on the difference value. That is, the amount of moisture dried near the exhaust port from the blank value (initial moisture value) is grasped, and if the outside humidity (dew point) is known, the equilibrium moisture content can be measured in advance. Thus, based on the difference between the water content and the equilibrium water content, it can be seen how much water was discharged from the vicinity of the exhaust port. One or both of the level meter and the air volume adjusting means are operated so that the moisture content calculated in this way coincides with the target moisture content, so as to control the moisture content to an appropriate value.

[0015]

When the material to be dried supplied into the drying hopper is heated by the drying gas, the material is evaporated in accordance with the amount of water, and the drying gas contains water in proportion to the amount of the evaporated water. Will be. Therefore, the temperature and the humidity sensor detect the temperature and humidity of the drying gas at any point from the supply of the drying gas to the drying hopper to the discharge thereof.

Next, based on the detected values of the temperature and the humidity, operation of control means such as a level meter and an air volume adjusting means prevents the material supplied into the drying hopper from being over-dried or undried. In this way, the water content of the material is properly controlled.

In the case where a mobile level meter is used as the control means, if the moisture content of the detected material is higher than the target moisture content, the mobile level meter is moved upward to move the material into the drying hopper. Is increased, and the residence time of the material, that is, the drying time is lengthened to increase the degree of drying so that the target moisture content is obtained. Conversely, when the moisture content of the detected material is lower than the target moisture content, the level meter is lowered to reduce the amount of the material filled in the drying hopper and shorten the residence time (drying time) of the material. In order to reduce the degree of drying and prevent overdrying, the water content is adjusted to a target.

When the air volume adjusting means is used as the control means, when the detected moisture content of the material is higher than the target moisture content, the air volume adjusting means is operated so as to increase the amount of hot air supplied to the air supply passage. Adjust to increase the degree of dryness to achieve the target moisture content. Conversely, when the moisture content of the detected material is lower than the target moisture content, the hot air volume is reduced by operating the air volume adjusting means to reduce the degree of drying so that the target moisture content is obtained so as not to be over-dried. To

In the case where temperature control means such as a thermostat is used as the control means, when the water content of the detected material is higher than the target water content, the temperature control means is operated by operating the temperature control means.
The temperature of the hot air supplied into the drying hopper is increased so that the target moisture content is obtained. Conversely, when the water content of the detected material is lower than the target water content, the temperature of the hot air is lowered by operating the temperature adjusting means so that the target water content is obtained.

When the humidity control means is used as the control means, when the moisture content of the detected material is higher than the target water content, the humidity control means operates the humidity control means to control the humidity of the drying gas supplied into the drying hopper. To achieve the target moisture content. Conversely, when the moisture content of the detected material is lower than the target moisture content, the operation of the humidity control means
The humidity of the drying gas is lowered so that the target moisture content is obtained.

The above-mentioned level gauge, air volume adjusting means, temperature adjusting means and humidity adjusting means may be used in appropriate combination to adjust the material filling amount, hot air amount, temperature or humidity of the drying gas arbitrarily.

Further, the present invention detects a fluctuation value of a molding state which influences molding such as pressure, temperature and time during molding in a molding machine connected downstream of a drying hopper. Based on this detected value, the control unit such as the level meter, the air volume control unit, the temperature control unit, and the humidity control unit determines whether the material supplied into the drying hopper is in an over-dried state or an undried state, as described above. By avoiding this, moisture management of the material can be properly performed. Note that the fluctuation value of the molding state refers to values of various factors that affect molding such as pressure, temperature, and time during injection molding or extrusion molding.

[0023]

First Embodiment A first embodiment of a drying apparatus according to the present invention will be described below with reference to FIG. A drying hopper 1 stores a material to be dried. A material collecting container 3 is provided on a top plate 2 of the drying hopper 1, and a material suction blower connected to the material collecting container 3. The material M stored in the storage tank 5 is sucked and transported to the material collecting container 3 through the suction nozzle 6 and the transport pipe 7 by the force of 4, and the material M in the material collecting container 3 opens the damper 8. Is supplied into the drying hopper 1.

An air passage 10 is provided on the side wall 9 of the drying hopper 1.
A drying gas conduit 11 is connected, a heating means 12 is provided at a distal end of the drying gas conduit 11, and a dehumidifying unit 13 is provided at a distal end side of the air supply passage 10 so as to supply dehumidified air having a low dew point. , Each is attached. The dehumidification unit 13 is provided with an air source 14 so as to be able to communicate with the air supply passage 10. The air (gas) from the air source 14 is dehumidified by the adsorbent 15, and the obtained dehumidified air (gas) having a low dew point is obtained.
Is heated by the heating means 12, and the heated air (gas) is supplied into the drying hopper 1 from the ejection port 11a of the drying gas conduit 11, and the material in the drying hopper 1 is dried.

The dehumidifying unit 13 has a regeneration air source 16
Adsorbent 15 consisting of a regeneration heater 17 and a regeneration conduit 18
A regenerating means for regenerating is provided, and 19 is a temperature sensor including a thermocouple for controlling a regenerating temperature.
The dehumidifying unit 13 is not limited to the configuration shown in FIG.

The air inlet 14 a of the air source 14 is provided with an exhaust port 20 formed in the top plate 2 of the drying hopper 1 and an exhaust path 2.
1 are connected by an exhaust pipe 22. Therefore, from the air source 14 of the dehumidifying unit 13, the adsorbent 15, the heating means 12, the drying hopper 1, and the exhaust port 20
The line returning to 4 forms a closed circulation circuit A via the air supply passage 10 and the exhaust passage 21. 23 in the figure
Indicates a cooler.

The material M dried by the drying hopper 1 is discharged out of the system from the material outlet 24 by opening the damper 25. In this embodiment, the plastic molding machine 26 is used.
The dried material is injection-molded by the molding machine 26 to obtain a desired molded product.

A temperature sensor and a humidity sensor (including a dew point meter) are provided at appropriate places in the circulation circuit A. In this embodiment, the first humidity sensor D1 provided between the dehumidifying unit 13 (air source 14) and the heating means 12 is used as the humidity sensor.
A second humidity sensor D2 provided near the material outlet 24 of the drying hopper 1, a third humidity sensor D3 provided near the exhaust port 20 of the drying hopper 1, and an exhaust passage 21 upstream of the cooler 23. A fourth humidity sensor D4 and a fifth humidity sensor D5 for a material outlet atmosphere (for outside air) are provided. In addition, although not shown, it may be provided between the material outlet 24 and the molding machine 26 or at another location. The reason that the moisture content of the material is measured by these humidity sensors (particularly, D2, D3, and D4) is that the material heated and dried in the drying hopper 1 evaporates in accordance with the amount of moisture, so that the exhaust port 20 is used. This is because the absolute humidity of the air (drying gas) discharged from to the circulation circuit A indicates a value corresponding to the moisture content of the material. Note that an online moisture meter 27 can be provided near the material outlet 24.

In this embodiment, the temperature sensor detects the drying temperature heated by the heating means 12.
Drying gas conduit 1 between the heating means 12 and the drying hopper 1
1, a second temperature sensor T2 provided near the exhaust port 20, and a third temperature sensor T3 for detecting the temperature of the upper portion of the material M stored in the drying hopper 1.
And In addition, although not shown, the drying hopper 1 can be provided with a number of temperature sensors in a stepwise manner in the height direction according to the height of the material M to be stored. For example, according to the temperature sensor T2, the temperature distribution in the drying hopper 1 can be estimated, and the heat history can be determined. When the thermal history is known, the moisture rate of the material becomes clear because the drying rate is known.

The humidity sensors D1 to D5 and the temperature sensors T1 to T3 are electrically connected to the controller 30, and the humidity sensors D1 to D5 and the temperature sensors T1 to T3 are connected.
Measurement data is input (2 in FIG. 1).
See dotted line). Although not shown, the controller 30
An arithmetic circuit, a comparison circuit, a temperature setting circuit, a humidity setting circuit, a driving circuit, and the like are connected. Therefore, the controller 3
0, each humidity sensor D1 to D5 and each temperature sensor T1 to
After the measured values of the humidity and temperature of the drying gas (air) are input from T3, the absolute humidity is calculated, and the measured absolute humidity is compared with the target value to output the target value. A signal is transmitted to drive the level meter 40 and the air volume adjusting means 50 to control the absolute humidity of the drying gas (air) to a target value (see a two-dot chain line in FIG. 1). Thus, the absolute humidity of the drying gas indicates a value corresponding to the moisture content of the material, so that the moisture content of the material can be adjusted to a desired value.

The level meter 40 includes the humidity sensors D1 to D
5, the filling level of the material M supplied into the drying hopper 1 is adjusted based on the detected value of any one or more of the materials, and the level position of the material can be moved so that the target moisture content is obtained. Is what you do. If the moisture content of the detected material is higher than the target moisture content, the mobile level meter 40
Is moved upward (at the position of the level meter 40 indicated by the solid line in FIG. 1), the amount of the material M filled in the drying hopper 1 is increased, and the residence time of the material, that is, the drying time is lengthened. To achieve the target moisture content. Conversely, when the moisture content of the detected material is lower than the target moisture content, the level meter 40 is moved downward (at the position of the level meter 40 indicated by the chain line in FIG. 1) and The retention time (drying time) of the material M is reduced by shortening the filling amount of the material M into the material, so that the target moisture content is obtained so as to reduce the degree of drying and prevent overdrying.

The air volume adjusting means 50 is provided with the humidity sensor D1.
To D5 based on the detected value of any one or more of:
The amount of hot air supplied into the drying hopper 1 is adjusted so that a target water content can be obtained. The air volume adjusting means 50 may be an air volume adjusting valve 51 as shown in FIG. 1 or an inverter (not shown), but may be another device as long as the air volume can be adjusted.
In the figure, the air volume adjusting means 50 includes an air volume adjusting valve 51 and a motor 52 for driving the air volume adjusting valve 51. The motor 52 receives an output signal from the controller 30 and adjusts the degree of restriction of the air volume adjusting valve 51. By arbitrarily changing, the amount of hot air supplied into the drying hopper 1 from the air source 14 via the dehumidifying unit 13 and the heating means 12 can be automatically adjusted. However, the design can be changed so that the amount of hot air is manually adjusted without providing the motor 52. If the moisture content of the detected material is higher than the target moisture content, the material is adjusted by operating the air volume adjusting means 50 so as to increase the amount of hot air supplied to the air supply passage 10 and the drying gas conduit 11, and To achieve the target moisture content. Conversely, when the moisture content of the detected material is lower than the target moisture content, the hot air volume is reduced by operating the air volume adjusting means 50, and the target moisture content is obtained so as to reduce the degree of drying and prevent overdrying. To do.

Either the level meter 40 or the air volume adjusting means 50 can be selectively used, or both can be used simultaneously.

The absolute humidity detected by the first humidity sensor D1 is subtracted from the absolute humidity detected by the second humidity sensor D2, and the moisture content in the vicinity of the material outlet 24 of the drying hopper 1 is calculated based on the difference value. One or both of the level meter 40 and the air volume adjusting means 50 may be operated so that the calculated moisture content matches the target moisture content. The moisture content (moisture content, moisture content) in the vicinity of the material outlet can be calculated based on the difference value, and can be used as a substitute for a moisture meter.

Now, in FIG. 1, the air volume of the air source 14 is 8
0m ³ / Hr, the dew point detected by the first humidity sensor D1 is -4
0 ° C, the drying temperature in the drying hopper 1 is 100 °
C, drying capacity is 20 kg / Hr, second humidity sensor D2
It is assumed that the dew point detected by the third humidity sensor D3 is −36 ° C. and the dew point detected by the third humidity sensor D3 is 5 ° C. (average value). Then, the density of air at 100 ° C. is 0.946 kg ′ / m
³ , the absolute humidity (moisture content in wet air (kg) / dry air content in wet air (k)
g ') is as follows. First absolute with humidity sensors D1 humidity = .1161 × 10 over 3kg / kg '· · i absolutely by the second humidity sensor D2 humidity = 0.1745 × 10 ^over 3 kg / kg' · · b third humidity sensor D3 absolute humidity = 5.399 × 10 ^over 3 kg / kg '· · Ha by

(1) From the absolute humidity by the second humidity sensor D2, it can be found from the difference between the absolute humidity by the first humidity sensor D1. The b - b = (0.1745 × 10 ^over 3 -0.1161 × 10 ^over 3) kg / kg '= 0.0584 × 10 ^over 3 kg / kg' ·· Thus two, only shown in the two water The rate has increased. On the other hand, since 80 m ³ / Hr air is supplied,
When this is converted to a weight, so that ^{the 80m 3 /Hr×0.946kg'/m 3 = 75.68kg '/} Hr ·· weight of the air ho is flowing. Therefore, when the moisture content of the above d is converted into the amount of increase in water per unit time, the amount of increase in water per unit time = d x e = 0.0584 x 10 m ^-3 kg / kg 'x 75.68 kg' / Hr = since moisture increase of f to 4.4197 × 10 ^{over 3} kg / Hr · · are those generated from the material being processed in 20 kg / Hr, dried moisture content near the material outlet of the drying hopper 1 the evaporation amount of water (kg / Hr) / weight of the material (kg / Hr) = 4.4197 × 10 ^over 3 kg / Hr ÷ 20 = 0.22 × 10 ^-3 = 0.00022 = 0.022 (% ) = 220 ppm. That is, it can be seen that the drying at 220 ppm has progressed near the material outlet 24 of the drying hopper 1. In other words, 220 ppm of moisture was dried from the material.

As described above, when the difference value obtained by subtracting the absolute humidity detected by the first humidity sensor D1 from the absolute humidity detected by the second humidity sensor D2 is higher than a predetermined value, the material is in an undried state. Indicates that drying is in progress. At this time, an alarm is displayed, or the level position of the above-mentioned level meter 40 is raised to extend the residence time (drying time) of the material in the drying hopper 1 so that the target moisture content is achieved. . Alternatively, the amount of hot air supplied into the drying hopper 1 is increased by the air volume adjusting means 50 so that the target water content is achieved.

If the difference value is lower than the predetermined value, it is determined that the material is in an over-dried state. Also at this time, an alarm is displayed or, contrary to the above case, the level position of the level meter 40 is lowered to shorten the residence time (drying time) of the material in the drying hopper 1 and reduce the target water content. Rate. Alternatively, the drying hopper 1
The amount of hot air supplied to the inside is reduced so that the target moisture content is obtained. In order to know the appropriate value of the water content, the water content is separately measured and the water content is controlled by the dew point value at that time.

The absolute humidity detected by the first humidity sensor D1 is subtracted from the absolute humidity detected by the third humidity sensor D3, and the water content in the vicinity of the material outlet 24 of the drying hopper 1 is calculated based on the difference value. One or both of the level meter 40 and the air volume adjusting means 50 may be operated so that the calculated moisture content matches the target moisture content.

Under the same conditions and numerical values as those described in the above [0043], it will be described below how to determine from the difference between the absolute humidity by the third humidity sensor D3 and the absolute humidity by the first humidity sensor D1. Absolute humidity by the third humidity sensor D3−Absolute humidity by the first humidity sensor D1 = (5.399 × 10 ⁻³ −0.1161 × 10 ⁻³ ) kg / kg ′ = 5.286 ×× 10 ⁻³ kg / kg '··· H Therefore, the moisture content increased as shown in the above-mentioned H. Therefore, when the moisture content of the above h is converted into the amount of water increase per unit time, the amount of water increase per unit time = h × ho = 5.286 × 10 ⁻³ kg / kg ′ × 75.68 kg ′ / Hr = since moisture increase of 400.0445 × 10 ^over 3 kg / Hr · · Li this list are those generated from the material being processed in 20 kg / Hr, dried at around outlet 20 of the drying hopper 1 moisture rate the evaporation amount of water (kg / Hr) / weight of the material (kg / Hr) = 400.0445 × 10 ^over 3 kg / Hr ÷ 20 = 20.0022 × 10 ^{over 3} ≒ 0.02 = 2 (%) .. Nu From the above-mentioned nu, it can be seen that 2% of moisture was dried from the exhaust port 20 based on the initial moisture value (blank value) which is the moisture value before drying the material.

The initial moisture value (blank value) can be determined by determining the equilibrium moisture content of the material in advance if the outside air dew point (in FIG. 1, for example, the dew point measured by the fifth humidity sensor D5) is known. Is 3%, for example, 3% -2
% = 1% has been discharged. The change in the initial moisture when the crusher or the material is changed from lot to lot has the same tendency as the change in the dry moisture due to the dew point difference, so that the change in the initial moisture can be grasped.

As described above, when the difference value obtained by subtracting the absolute humidity detected by the first humidity sensor D1 from the absolute humidity detected by the third humidity sensor D3 is high (large), the evaporated water is removed from the system. That they are being discharged more and more,
In other words, it means that the drying rate is high, the initial moisture of the material is large, or the supply amount of the material is large, which indicates that the material is being dried in an undried state. At this time, an alarm is displayed, or the level position of the above-mentioned level meter 40 is raised to extend the residence time (drying time) of the material in the drying hopper 1 so that the target moisture content is achieved. . Alternatively, the amount of hot air supplied into the drying hopper 1 is increased by the air volume adjusting means 50 so that the target water content is achieved.

When the difference value is lower than the predetermined value, it is determined that the material is in an over-dried state. Also at this time, an alarm is displayed or, contrary to the above case, the level position of the level meter 40 is lowered to shorten the residence time (drying time) of the material in the drying hopper 1 and reduce the target water content. Rate. Alternatively, the drying hopper 1
The amount of hot air supplied to the inside is increased so that the target moisture content is obtained.

An increase in the drying rate under the same drying conditions indicates that a material having a high moisture content was dried.
This can be seen from the drying curve in FIG. 4 and the drying characteristic curve in FIG. That is, when the water content is high, the slope of the drying time curve in FIG. 4 is steep, and in FIG. 5, the drying speed is high. As the water content becomes lower, the slope of the curve of the drying time in FIG.
Then, the drying speed becomes lower (slower) sequentially.

The data of the variable of the molding state such as the injection pressure, the injection temperature and the time in the molding machine 26 connected to the downstream side of the drying hopper 1 is inputted to the controller 30 and the inputted variable element is inputted. The measured value is compared with a desired target value (set value). When the measured value is an appropriate value as shown in FIG.
Since the moisture content of the material is presumed to be normal, molding operations such as injection and extrusion are performed continuously. When the measured value is an injection pressure higher than the target value as shown in FIG. 3B, the water content of the material is lower than the allowable water content and the material is in the over-dried state, and the measured value is the target value as shown in FIG. If the injection pressure is lower than the value, it can be estimated that the moisture content of the material is higher than the allowable moisture content and is in an undried state. Therefore, when the molding operation is performed in the cases b and c described above, a defective molding occurs.

Therefore, as shown in FIGS. 3B and 3C, when a variable in the molding state such as the injection pressure of the molding machine 26 is out of the proper range (that is, abnormal), an alarm is issued.
Alternatively, a fluctuation value of the molding state in the molding machine 26 is detected, and based on the detected value, the level position of the level meter 40 is moved to adjust the filling amount of the material supplied into the drying hopper 1, and Try to manage moisture. Alternatively, the air volume of the drying gas supplied into the drying hopper is adjusted by the air volume adjusting means 50 based on the detected value to control the moisture of the material. Further, it is also possible to simultaneously control both the level meter 40 and the air volume adjusting means 50 to manage the moisture of the material. Further, based on the detected value, the temperature of the drying gas can be adjusted by a temperature adjusting means (not shown) such as a thermostat, or the humidity of the drying gas can be adjusted by a dehumidifier (not shown). .

The first drying method of the present invention using the above-described drying apparatus according to the first embodiment of the present invention will be described below. (1) A drying gas is supplied to the drying hopper 1 to dry the material M, and the dried drying gas is discharged from the drying hopper 1 as exhaust gas. (2) In the meantime, the temperature and humidity at an arbitrary point from the supply of the drying gas to the time after the drying gas are discharged are measured by a temperature sensor (T1).
To T3...) And humidity sensors (D1 to D5...). (3) Next, the detected values, particularly the humidity sensors (D1 to D
5), the material level position of the level meter 40 is moved to adjust the filling amount of the material supplied into the drying hopper 1 so as to obtain the target moisture content for the material. To

In the second drying method of the present invention, the operations (1) and (2) are performed in the same manner, but the operation for obtaining the final target moisture content is different. That is, as the last operation, in particular, based on the detection values of the humidity sensors (D1 to D5...)
The air volume adjusting means 50 adjusts the air volume of the hot air supplied into the drying hopper 1 so as to obtain a target moisture content for the material.

In the third drying method of the present invention, the above operations (1) and (2) are performed in the same manner, but the operation for obtaining the final target water content is different. That is, as the last operation, in particular, based on the detection values of the humidity sensors (D1 to D5...)
The temperature of the drying gas is adjusted by the temperature adjusting means (not shown), and the humidity of the drying gas is adjusted by the humidity adjusting means (not shown) such as the dehumidifier. To obtain a water content of

The fourth drying method of the present invention has the following effects: (1) Influences the pressure, temperature, time, etc., during injection molding or extrusion molding in a molding machine 26 connected downstream of the drying hopper 1. The value of the variable component of the molding state is detected.
(2) Based on the detected value, the level position of the material of the level meter 40 is moved to adjust the filling amount of the material supplied into the drying hopper 1 so as to obtain a target moisture content for the material. .

In the fifth drying method of the present invention, the above-mentioned operation (1) is performed in the same manner, but the operation for obtaining the target moisture content includes the air volume adjusting means 50 based on the detection of the fluctuation value of the molding state. By controlling the flow rate of the drying gas supplied into the drying hopper, the target moisture content of the material is obtained.

[0052]

Second Embodiment FIG. 2 is a schematic diagram showing a drying apparatus according to a second embodiment of the present invention. The second embodiment differs from the first embodiment in FIG. 1 in that the air supply passage 10 and the exhaust passage 21 are not connected to a closed circuit, and the dehumidifying unit 13 and the controller 30 are different from each other. Not provided, the position of the air volume adjusting means 50 is different,
The difference is that the number and the mounting position of the temperature sensor and the humidity sensor are different, but other configurations are substantially the same, so that the detailed description is omitted and the same reference numerals are given for convenience.

The drying hopper 1 is provided with second, third, and fourth temperature sensors T2, T3, and T4.
1 is a one-pass (open) type. A humidity sensor D5 for outside air may be provided. An air source 14 is connected to one end of the air supply passage 10, and an air volume adjusting valve 51, which is an air volume adjusting unit 50, is connected to the heating unit 12. The humidity sensor includes first, second, and third humidity sensors D1, D2, and D3 at positions similar to those in FIG.

The level meter 40 includes humidity sensors (D1 to D3).
...), the level of the material is adjusted such that the target water content is obtained by adjusting the filling amount of the material M supplied into the drying hopper 1 based on the detected value of at least one of the materials. It is intended to be movable. If the moisture content of the detected material is higher than the target moisture content, the movable level meter 40 is moved upward (at the position of the level meter 40 indicated by a solid line in FIG. The retention time of the material, that is, the drying time is increased by increasing the amount of the material M filled in the material, and the degree of drying is increased so that the target moisture content is obtained. Conversely, when the moisture content of the detected material is lower than the target moisture content, the level meter 40 is moved downward (at the position of the level meter 40 indicated by a chain line in FIG. The retention time (drying time) of the material M is reduced by shortening the filling amount of the material M into the material, so that the target moisture content is obtained so as to reduce the degree of drying and prevent overdrying.

The air volume adjusting means 50 is provided with the humidity sensor D1.
To D3 based on the detected value of any one or more of:
The amount of hot air supplied into the drying hopper 1 is adjusted so that a target water content can be obtained. When the moisture content of the detected material is higher than the target moisture content, the material is adjusted by operating the air volume adjusting means 50 so as to increase the amount of hot air supplied to the air supply passage 10 and the drying gas conduit 11,
Increase the degree of drying to achieve the target moisture content. Conversely, if the target moisture content of the detected material is low, the hot air volume is reduced by operating the air volume adjusting means 50, and the target moisture content is reduced so as to reduce the degree of drying and prevent overdrying. To do.

Either the level meter 40 or the air volume adjusting means 50 can be selectively used, or both can be used simultaneously.

Each of the temperature sensors T1 to T4, the humidity sensors D1 to D3, the level meter 40, and the air volume adjusting means 50 in FIG.
As shown in FIG. 1, it is preferable to connect to the controller 30 so that the level meter 40 and the air volume adjusting means 50 are automatically controlled.

[0058]

(1) According to the first aspect of the present invention, at least the drying hopper, the air source, the temperature sensor, and the humidity sensor are provided, and the level meter which can move the level position of the material in the drying hopper is provided. Since, based on the detection value of the humidity sensor, the filling amount of the material supplied into the drying hopper is adjusted to obtain the target moisture content, the moisture content of the material is equal to or more than an appropriate value. When it comes
Immediately adjusting the filling amount of the material and controlling the water content so as to obtain an appropriate value (target value) of water content, the material can be dried as a continuous drying method in which the material is continuously supplied and dried. In addition, as described above, by merely adjusting the filling amount of the material, the over-dried state and the undried state are not eliminated, and the quality of a product such as a molded product can be improved. Further, since overdrying of the material can be prevented, heat energy required for drying is reduced, which can contribute to cost reduction.

(2) According to the second aspect of the present invention, in the first aspect, an air flow rate adjusting means is provided in addition to the level meter, and the level meter and the air flow rate adjusting means can be used selectively or simultaneously. In addition, an appropriate moisture content can be maintained, poor drying of the material can be more effectively eliminated, and improvement in product quality and reduction in energy consumption can be further improved.

(3) According to the third aspect of the present invention, the absolute humidity detected by the first humidity sensor is subtracted from the absolute humidity detected by the second humidity sensor, and the difference value near the material outlet of the drying hopper is determined based on the difference value. , The moisture content of the material can be easily measured by a simple and inexpensive humidity sensor without using a conventional expensive and large-scale moisture measuring device. In this case, one or both of the level meter and the air volume adjusting means are operated so as to control the water content to an appropriate value so that the calculated water content matches the target water content.

(4) According to the fourth aspect of the present invention, the absolute humidity detected by the first humidity sensor is subtracted from the absolute humidity detected by the third humidity sensor, and the difference value near the material outlet of the drying hopper is determined based on the difference value. And one or both of the level meter and the air volume adjusting means are operated so that the calculated moisture content matches the target moisture content, so that the material is controlled to have a more appropriate moisture content. can do.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a first embodiment of a drying apparatus according to the present invention.

FIG. 2 is a schematic configuration diagram of a second embodiment of a drying apparatus according to the present invention.

FIG. 3 is a graph showing a relationship between moisture of a material and an injection pressure.

FIG. 4 is a graph showing the relationship between the water content and the drying time.

FIG. 5 is a graph showing a relationship between a water content and a drying speed.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Drying hopper 10 Air supply path 12 Heating means 13 Dehumidification unit 14 Air source 20 Exhaust port 21 Exhaust path 22 Exhaust pipe 24 Material outlet 26 Molding machine 30 Controller 40 Level meter 50 Air volume adjusting means 51 Air volume adjusting valve D1 First humidity sensor D2 Second humidity sensor D3 Third humidity sensor D4 Fourth humidity sensor D5 Fifth humidity sensor T1 First temperature sensor T2 Second temperature sensor T3 Third temperature sensor M Material A Circulation circuit

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification code FI F26B 25/22 F26B 25/22 Z (72) Inventor Osamu Matsui 6-5-26 Tanimachi, Chuo-ku, Osaka-shi, Osaka (56) References JP-A-62-162880 (JP, A) JP-A-54-135853 (JP, A) JP-A-2-1977791 (JP, A) JP-A-57-150777 (JP, A) JP-A-4 -5005 (JP, A) JP-A-61-83870 (JP, A) JP-A-54-103463 (JP, A) JP-A-2-227213 (JP, A) JP-A-6-344383 (JP, A) JP-A-54-94101 (JP, A) Jiko 1-36581 (JP, Y2) (58) Fields investigated (Int. Cl. ⁷ , DB name) F26B 21/08-21/12 F26B 25 / 00,25 / 22 B29B 13/06

Claims (4)

(57) [Claims] 1. A drying hopper for containing a material to be dried, an air source for feeding hot air for drying the material into the drying hopper, and an air source from the air source through an air supply path and a drying hopper to an exhaust path. The provided temperature sensor and humidity sensor
A drying apparatus for at least a powdery / granular material, comprising: adjusting a filling amount of a material supplied into the drying hopper based on a detection value of the humidity sensor so as to obtain a target moisture content. An apparatus for drying a granular material, comprising a level meter capable of moving the level position. 2. A drying hopper for containing a material to be dried, an air source for feeding hot air for drying the material into the drying hopper, and an air source from the air source through an air supply path and a drying hopper to an exhaust path. The provided temperature sensor and humidity sensor
A drying apparatus for at least a powdery / granular material, comprising: adjusting a filling amount of a material supplied into the drying hopper based on a detection value of the humidity sensor so as to obtain a target moisture content. And a level meter that can move the level position of the hot air and an air volume adjusting means that adjusts the air volume of the hot air supplied into the drying hopper so as to obtain a target moisture content. Drying device for granular material. 3. A humidity sensor provided between an air source and a heating means, a second humidity sensor provided near a material outlet of a drying hopper, and a second humidity sensor provided near an exhaust port of the drying hopper. And at least a first humidity sensor based on the absolute humidity detected by the second humidity sensor.
The absolute humidity detected by the humidity sensor is subtracted, the moisture content in the vicinity of the material outlet of the drying hopper is calculated based on the difference value, and the level meter and the air volume adjusting means are adjusted so that the calculated moisture content matches the target moisture content. The apparatus for drying a granular material according to claim 1 or 2, wherein one or both of them are operated. 4. A humidity sensor provided between an air source and a heating means, a second humidity sensor provided near a material outlet of a drying hopper, and a second humidity sensor provided near an exhaust port of the drying hopper. At least a third humidity sensor, and a first humidity sensor based on the absolute humidity detected by the third humidity sensor.
The absolute humidity detected by the humidity sensor is subtracted, the moisture content in the vicinity of the material outlet of the drying hopper is calculated based on the difference value, and the level meter and the air volume adjusting means are adjusted so that the calculated moisture content matches the target moisture content. The apparatus for drying a granular material according to claim 1 or 2, wherein one or both of them are operated.