JPH02303471A - Vacuum drier by microwave heating - Google Patents

Abstract

PURPOSE:To obtain the subject drier capable of making an outside vessel light, making occurrence of discharge therein difficult and shortening deaeration time by providing a vacuum vessel made of a material capable of passing microwave through the interior of the outside vessel. CONSTITUTION:A material 42 to be dried is put into a vacuum vessel 20 and microwave is introduced from a microwave oscillator 14 and passed into the vacuum vessel 20. The material 42 to be dried is rapidly dried in low temperature by evacuating the vacuum vessel by a vacuum device 38 and lowering boiling point of water. The outside vessel 10 is made of a thin metal plate and the weight is made light.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention relates to a microwave heating vacuum dryer.

(b) Conventional technology A microwave heating vacuum dryer uses microwaves to internally heat the material to be dried while reducing the pressure.
This is a quick drying device. Conventional microwave heating vacuum dryers are configured to introduce microwaves into a vacuum container. That is, as shown in FIG. 7, the conventional microwave heating vacuum dryer includes five vacuum containers 50, a vacuum device 52 capable of reducing the pressure inside the vacuum container 50, and a micro waveguide 54 passed through the vacuum container 50. It has a microwave oscillator 56 capable of introducing 11 waves, a turntable 58 provided in the vacuum container 50, and a drive device 60 for rotationally driving the turntable 58. It is installed on a turntable 58. Vacuum container 5
0 has a door 50a, and by opening and closing this door, the material to be dried 62 is taken in and taken out. The object 62 to be dried on the turntable 58 is uniformly irradiated with microwaves, and at the same time the inside of the vacuum chamber 50 is evacuated, so that the object 62 to be dried is internally heated and water is evaporated under reduced pressure. , drying takes place quickly.

(c) Problems to be Solved by the Invention However, the conventional microwave heating vacuum dryer as described above has a problem in that the vacuum container 50 is large and heavy. That is, the vacuum volume 'a50 needs to have enough rigidity to withstand a predetermined vacuum, and it is necessary to use a metal material with a large wall thickness, and as the size increases, the weight also increases. As the internal volume of the vacuum container 50 increases, its weight increases significantly. Furthermore, in conventional microwave heating vacuum dryers, in order to increase the degree of vacuum, it is necessary to suppress the microwave output, and the degree of vacuum is practically limited to 40 to 50 Torr.

The lower the pressure in the vacuum chamber 50, the lower the drying temperature, but if the pressure is too low, electrical discharge will occur in the vacuum container 50, which will consume microwave energy. Discharge is particularly likely to occur near the exit of the waveguide 54 where the microwave power is high. The relationship between the electric power of the microwave that starts the discharge and the degree of vacuum is as shown in FIG. 8, and the degree of vacuum is set to about 40 to 50 Torr as described above in order to prevent the occurrence of discharge. The present invention aims to solve these problems.

(d): Means for Solving Problem 5 The present invention solves the above problem by providing a vacuum container that allows microwaves to pass inside an outer container that prevents leakage of microwaves. That is, the microwave heating vacuum dryer according to the present invention includes an outer container (10) configured to prevent microwaves from leaking to the outside, and a microwave oscillator (technique 4) capable of outputting microwaves into the outer container. , a vacuum container (20) disposed in the outer container, a rotation drive mechanism (34, 30, 32, 18) that rotates the entire vacuum container or a turntable (44) in the vacuum container, and It has a vacuum device (38) capable of reducing pressure, and at least a part of the vacuum container is made of a material that allows passage of microwaves. Note that the symbols in parentheses indicate corresponding members in the embodiments described later.

(e) Effect The material to be dried is placed in a vacuum container, and the pressure inside the vacuum container is reduced.

Microwaves are introduced from a microwave oscillator while the vacuum container or the turntable inside the vacuum container is rotated by a rotation drive mechanism. Since the vacuum container allows passage of microwaves, the material to be dried is heated from inside by the microwaves. At the same time, as the pressure is reduced, the boiling point of water decreases, and as the water evaporates, heat is removed, and drying is performed quickly at low temperatures. Since no vacuum is applied to the outer container, it can be made from a thin metal plate and is therefore lighter. In addition, since the microwave introduction part with the highest microwave power is at atmospheric pressure, discharge is less likely to occur, and the degree of vacuum in the vacuum container can be increased. Furthermore, since the volume inside the vacuum container is small, the evacuation time by the vacuum evacuation device can be shortened.

(f) Example (First Example) A thin metal outer container IO, which shows a first example in FIGS. 1 and 2, has a door 10a that can be opened and closed. door 10
A stainless steel mesh contact piece 12 is provided on the contact surface with a to prevent microwave leakage. A microwave oscillator 14 is provided at the top of the outer container 10, from which microwaves can be introduced into the outer field Hio through a waveguide 16. A vacuum container 20 supported by a rotating shaft 18 is provided inside the outer container IO. The vacuum container 20 has a lid 20a, and the contact portion of the lid 20a is kept airtight by a gasket 22. The vacuum container 20 is made of a material that allows microwaves to pass, such as quartz, fluororesin, glass, polypropylene resin, FRP, etc. Rotation Ipth18
is rotatably supported by bearings 24 and 26 on a member 28 integral with the outer container 10. A bevel gear 30 is provided integrally with the rotating shaft 18, and this bevel gear 3
A bevel gear 32 meshing with the gear 0 can be rotationally driven by a motor 34. Motor 34, bevel gear 32, bevel gear 3
4 and the rotating shaft 18 constitute a rotational drive mechanism that rotationally drives the vacuum container 20. A vacuum passage 36 communicating with the inside of the vacuum container 20 is provided at the center of the rotating shaft 18, and the other end of the vacuum passage 36 is connected to a vacuum evacuation device 38. Note that a vacuum seal member 40 is provided between the member 28 and the rotating shaft 18 to prevent vacuum from leaking.

Next, the operation of this embodiment will be explained.

First, open the door i0a of the outer container 10, remove the lid 20a of the vacuum container 20, and place the material to be dried in the vacuum container 20.
2, close the lid 20a, and close the door 10a. Next, the vacuum device 38 is operated to remove the vacuum container 2.
Start depressurizing within 0. At the same time, the motor 34 is operated to rotate the vacuum container 20. Also, the microwave oscillator 14 is activated, and the waveguide 16 is passed through the outer container 10.
Introducing microwaves inside. Vacuum container 20 as described above
is made of a material that allows microwaves to pass through, so the microwaves act on the material to be dried 42 and heat it from within.

As the pressure inside the vacuum container 20 is reduced, the boiling point of water is lowered, and the moisture contained in the material to be dried 42 is vaporized by heating from inside and the pressure is reduced, and the material to be dried 42 is cooled. It is dried at the same time. Therefore, the material to be dried 42
It can be dried quickly without increasing the temperature. After reducing the pressure inside the vacuum container 20 to a predetermined degree of vacuum, the atmosphere is introduced, the motor 34 and the microwave generator 14 are stopped, the door 10a and the lid 20a are opened, and the dried material 42 is removed. . As mentioned above, the outer container 1
0 is manufactured from a thin metal plate, and is small and lightweight, since it is sufficient that microwaves are reflected internally and not leaked to the outside.
It is J1. Further, the vacuum container 20 only needs to have a size that can accommodate the material to be dried 42, and since it is very small compared to conventional vacuum containers, it can be made of glass, polypropylene resin, FRP, etc. Thin walls can be used. Furthermore, since the volume of the vacuum container 20 is small, the evacuation time from atmospheric pressure to a predetermined degree of vacuum can be shortened, or the capacity of the evacuation device 38 can be reduced.

In addition, since the area near the output of the waveguide 16, where the highest microwave power is generated, is at atmospheric pressure, the discharge phenomenon is less likely to occur in this area, and the degree of vacuum in the vacuum vessel 20 can be increased. It is also possible to increase the input energy of microwaves and increase the drying rate.

(Second Embodiment) A second embodiment is shown in FIGS. 3 and 4. In this second embodiment, a turntable 44 is provided inside the vacuum container 20, and the material to be dried 42 is placed on top of the chamber. The vacuum container 20 does not rotate, and only the turntable 44 rotates. Accordingly, the arrangement of the vacuum suction device 38, motor 34, etc. is different from that of the first embodiment. In addition, the same reference numerals are given to the members corresponding to those of the first embodiment shown in FIGS. 1 and 2. In this second embodiment as well, the first
The same effect as in the embodiment can be obtained.

(Third Example) A third example is shown in FIGS. 5 and 6. In this third embodiment, a vacuum container 20 is divided into a plurality of (six in this example) chambers 21. Particularly when the vacuum container 20 is large, it is advantageous in terms of strength to divide it into a plurality of chambers 21.

(g) As described in detail, according to the present invention, a vacuum container made of a material that allows microwaves to pass through is provided inside the outer container, so that the outer container can be manufactured from a thin metal plate. It can be made lighter and lighter. In addition, since the introduction part of the microwave into the outer container is at atmospheric pressure, electric discharge is unlikely to occur, so it is necessary to increase the degree of vacuum in the vacuum container or increase the energy introduced by the microwave. This can speed up the drying rate. Furthermore, since the volume of the vacuum container is small, the evacuation time can be shortened or the capacity of the vacuum evacuation device can be reduced.

[Brief explanation of the drawing]

FIG. 1 shows the first embodiment, and FIG. 2 shows [1-
A view taken along IIm, FIG. 3 is a view showing the second embodiment,
4 is a view taken along the rV-rV line in FIG. 3, FIG. 5 is a view showing the third embodiment, FIG. 6 is a view taken along the IV-IV line in FIG. 5, FIG. 7 is a diagram showing a conventional microwave heating reduced pressure dryer, and FIG. 8 is a diagram showing the relationship between microwave power and degree of vacuum. 10...Outer container, 14...Microwave oscillator, 1
6... Waveguide, 18... Rotating shaft, 20... Vacuum container, 30.32... Kasa Ryoichi, 34... Sota, 3
8... Vacuuming device, 42... Material to be dried. Patent Applicant Nippon Seisho Co., Ltd. Agent Patent Attorney Toshiyuki Miyauchi Figure 8 - 2. Name of the invention Microwave heating vacuum dryer 3. Relationship with the person making the amendment Patent applicant address 1-2 Yurakucho-chome, Chiyoda-ku, Tokyo Name (Name) (4211 Japan Steel Works Co., Ltd. Representative Yagi) Naohiko 4, Agent 5 Date of amendment order 6, number of claims increased by amendment 7, column for title of invention of specification subject to amendment, column for scope of claims, and column for detailed description of invention 8 , Contents of the amendment (1. The title of the invention is amended to "Microwave heating reduced pressure drying method and dryer". (2. The scope of claims is amended as shown in the attached appendix. (3) Page 1 of the specification In line 16, ``Microwave heating vacuum dryer'' should be corrected to read ``Microwave heating vacuum drying method and dryer.'' (4) Page 4, line 4 to page 5, line 15 of the specification. ``The present invention is capable of microwave...''
[The present invention solves the above problem by providing a vacuum container that allows microwaves to pass inside an outer container that prevents leakage of microwaves. That is, in the microwave heating reduced pressure drying method according to the present invention, the material to be dried is placed in a vacuum container that allows passage of microwaves and is installed inside an outer container configured to prevent microwaves from leaking to the outside. It consists of reducing the pressure inside the vacuum container and outputting microwaves to the outer container and the inside of the container to dry the material to be dried. Further, the microwave heating vacuum dryer according to the present invention has an outer container (
10), a microwave oscillator (14) capable of outputting microwaves into the outer container, a vacuum container (20) disposed in the outer container, and a vacuum device (14) capable of reducing the pressure inside the vacuum container.
38), and at least a portion of the vacuum container is made of a material that allows passage of microwaves. Note that the symbols in parentheses indicate corresponding members in the embodiments described later. (E) Operation: Place the material to be dried in a vacuum container, reduce the pressure inside the vacuum container, and introduce microwaves from a microwave oscillator. Since the vacuum container allows passage of microwaves, the material to be dried is heated from inside by the microwaves. At the same time, as the pressure is reduced, the boiling point of water decreases, and as the water evaporates, heat is removed, and drying is performed quickly at low temperatures. Since no vacuum is applied to the outer container, it can be made from a thin metal plate and is therefore lighter. In addition, since the microwave introduction part where the microwave power is the highest is at atmospheric pressure, discharge is less likely to occur, and the degree of vacuum within the vacuum container can be increased. In addition, since the volume inside the vacuum container is small, the evacuation time using the vacuum evacuation device can be shortened.
It is also possible to introduce microwaves from a microwave oscillator while rotating the vacuum container or a turntable inside the vacuum container using a rotation drive mechanism. ” he corrected. (5) On page 10 of the specification, line 3: [Strongly advantageous.] "J" means "It is advantageous in terms of strength. In the above three examples, the vacuum container or turntable was rotated, but this was to apply the microwave as uniformly as possible, so it was not rotated once. It is also possible to do so.'' Claim 1: The material to be dried is placed in a vacuum container that allows passage of microwaves and is installed inside an outer container configured to prevent microwaves from leaking to the outside, and the pressure inside the vacuum container is reduced. Microwave heating reduced pressure drying method 2 in which microwaves are output into the outer container to dry the material to be dried, an outer container configured to prevent microwaves from leaking to the outside, and a microwave that can be output into the outer container It has a microwave oscillator, a vacuum container disposed in the outer container, and a vacuum device capable of reducing the pressure inside the vacuum container, and at least a part of the vacuum container is made of a material that allows passage of microwaves. Microwave heating vacuum dryer. 3. The microwave heating reduced pressure dryer according to claim 2, wherein the vacuum container is divided into a plurality of chambers. 4. The microwave heating reduced pressure dryer according to claim 2 or 3, further comprising a rotational drive mechanism for rotationally driving the vacuum container. 5. The microwave heating reduced pressure dryer according to claim 2 or 3, further comprising a rotational drive mechanism for rotating a turntable provided in the vacuum container in order to place the material to be dried.

Claims (1)

[Claims] An outer container configured to prevent microwaves from leaking to the outside, a microwave oscillator capable of outputting microwaves inside the outer container, a vacuum container placed inside the outer container, and a vacuum container configured to prevent microwaves from leaking to the outside. a rotation drive mechanism that rotates a turntable, and a vacuum device that can reduce the pressure inside the vacuum container, and at least a portion of the vacuum container is made of a material that allows passage of microwaves. Vacuum dryer.