JP6749601B2 - Natural convection dryer - Google Patents

Description

The present invention relates to a natural convection dryer for heating and drying an object.

The dryer is used for accommodating an object in a tank and performing heat treatment. An oven, which is a dryer of this type, is disclosed in Patent Document 1, for example. The tank of the dryer is formed in a box shape, has an opening/closing door, and the atmosphere in the tank is heated by a heater arranged under the bottom plate of the tank. The operator opens the door to place an object in the tank, then closes the door to heat the object in the tank, and then opens the door again to take out the object.

Further, as this type of dryer, a dryer in which a plurality of long holes are arranged on the entire bottom plate and heat is raised from the whole bottom plate through the plurality of long holes of the bottom plate to dry the object in the tank is proposed. .. A plurality of objects are arranged side by side on the shelf board.

JP 2007-271126 A

However, in a dryer that raises heat from the entire bottom plate surface through a plurality of long holes in the bottom plate as described above, it is necessary to prevent abnormal heating of an object placed on the lowermost shelf plate. In order to prevent abnormal heating of objects, the area of the empty space of the shelves is 30% or more of the total area of the shelves, excluding the total area occupied by the objects arranged side by side on the shelves. There is a rule to do so.

However, in the actual drying work, the worker may spread the objects over the entire area of the shelf board. In particular, when the object is spread over the lowermost shelf, there is no escape of heat under the lowermost shelf when increasing the temperature of the processing space.

In this way, since heat is accumulated under the lowermost shelf, the temperature of the temperature sensor for controlling the temperature inside the tank does not rise easily. Then, since the heater always continues to heat the air with an output of 100%, the target object becomes abnormally heated, and an unexpected temperature rise occurs in the target object. For example, when the object has a resin material, the resin portion may melt down.

The present invention has been made in view of the above, and an object thereof is to prevent the occurrence of heat accumulation under the bottom of the processing space such as the lowermost shelf and control the temperature of the processing space. It is to provide a dryer that can do.

To achieve the above object, a natural convection dryer according to the present invention is the natural convection dryer for drying and heating houses the object, as well as have the opening, a shelf board A main body having a processing space for accommodating and drying the object on the shelf, a door for opening and closing the opening of the main body, and a shelf for the lowermost shelf. A bottom plate which is below and constitutes the bottom of the processing space, and which forms an air path portion between the bottom shelf plate, a heater arranged at a position lower than the bottom plate, and the heater. An air flow path part for raising the heated air to convect the heated air in the main body part to heat the processing space, the air flow path part being opposite to the opening part. The rear side air flow path portion provided on the rear side of the processing space of the main body portion, and the position of one side surface and the other side surface of the opening portion, and the one side and the other side of the processing space of the main body portion. It is composed of a side air passage portion provided on the side surface side, the air heated by the heater is raised from the back side air passage portion and the side air passage portion, and the raised air is lowered from the opening side. It is characterized in that the air is circulated through the air path portion formed between the lowermost shelf plate and the bottom plate .

The natural convection dryer according to the present invention is provided with an air flow path section that raises the air heated by the heater to convect the air heated in the processing space in the main body section. For this reason, for example, even if the object is spread over the predetermined area on the lowermost shelf, the occurrence of heat accumulation under the bottom of the processing space is prevented, and the processing is performed. The temperature of the space (temperature in the tank) can be controlled.
The temperature of the heated air is the highest on the back side forming the processing space, and the temperature of the heated air is the lowest on the door side forming the processing space. For this reason, since the air flow path portion is provided on the back side of the processing space of the main body portion on the side opposite to the opening, it generates an upward airflow of heated air on the back side and heats it on the door side. It is possible to generate a descending air flow of air. Even when the heated air flow is created and the objects are spread over the predetermined area, the heat accumulation under the bottom of the processing space can be prevented.
In addition, the air flow path section generates an ascending air current of the heated air and a descending air current at the door side, thereby creating a heated air flow and making it possible to cover an area larger than a predetermined area. Even if the objects are spread out and arranged, it is possible to prevent heat accumulation under the bottom of the processing space.

Further, the natural convection dryer according to the present invention is characterized in that a side duct hole is formed on a side surface of the main body portion in the air path portion.
Further, the natural convection dryer according to the present invention is characterized in that a plurality of through holes are formed in the lowest shelf plate.

The natural convection dryer according to the present invention is disposed at a position below the bottom of the processing space of the main body, detects the temperature of the heated air by the heater, and outputs a temperature information signal. It is characterized by comprising a sensor and a control unit for controlling the temperature in the processing space by adjusting the output amount of the heater according to the temperature information signal from the temperature sensor.

In the natural convection dryer according to the present invention , the temperature sensor is arranged at a position lower than the bottom of the processing space, detects the temperature of the air heated by the heater and outputs a temperature information signal, and the control unit The temperature in the processing space is controlled by adjusting the output amount of the heater based on this temperature information signal. Therefore, the temperature sensor can linearly detect the temperature increase of the air heated by the heater at a position below the bottom of the processing space, and adjust the output amount of the heater earlier. By suppressing the surface temperature of the heater at an early stage, the temperature of the hot air introduced into the processing space from the bottom of the processing space can be lowered. Further, energy saving of the natural convection dryer can be achieved.

In the natural convection dryer according to the present invention, an exhaust port communicating with the air flow path is provided in an upper portion of the main body, a lid is arranged at the exhaust port, and the lid allows exhaust gas to pass therethrough. It is characterized by having a hole for.

In the natural convection dryer according to the present invention , the exhaust port is provided with a lid, and since this lid has a hole for passing exhaust gas, even if the exhaust port is closed with the lid, Exhaust is possible.

In the natural convection dryer according to the present invention, the lid can open the exhaust port.

In the natural convection dryer according to the present invention , the lid can open the exhaust port, so that the amount of exhaust can be increased when a large amount of exhaust is desired.

According to the present invention, it is possible to provide a natural convection dryer capable of controlling the temperature of the processing space by preventing heat accumulation under the bottom of the processing space such as the lowermost shelf.

It is a longitudinal cross-sectional view showing a preferred embodiment of the natural convection dryer of the present invention. It is sectional drawing in the MM line of the natural convection type dryer shown in FIG. It is a horizontal schematic diagram in the NN line of the natural convection type dryer shown in FIG. It is a horizontal schematic diagram in the PP line of the natural convection type dryer shown in FIG. It is a figure which shows the structural example of the vicinity of an exhaust port.

Hereinafter, modes for carrying out the present invention (hereinafter, referred to as embodiments) will be described with reference to the drawings.

FIG. 1 is a longitudinal sectional view showing a preferred embodiment of the natural convection dryer of the present invention. FIG. 2 is a cross-sectional view taken along line MM of the natural convection dryer shown in FIG.

The natural convection dryer 1 shown in FIG. 1 and FIG. 2 is a device used for drying instruments in, for example, a laboratory or a laboratory. The natural convection dryer 1 is used, for example, by a student or a researcher to heat and dry an object (object to be dried) such as a container or an instrument used for research. The natural convection type dryer 1 is a natural convection type natural convection type dryer which dries an object in a processing space (inside a tank) by causing natural convection of heated air in the tank.

As shown in FIGS. 1 and 2, the natural convection dryer 1 has a main body 2. The main body 2 is a box-shaped box made of metal having heat resistance. The main body portion 2 has a front surface portion 3, a back surface portion 4, a left side surface portion 5, a right side surface portion 6, a top surface portion 7, and a bottom surface portion 8.

As shown in FIG. 1, the front portion 3 has a front door 9. Although not shown, the front door 9 has an operation panel and a handle. The operation panel has a start switch and a stop switch for energizing the heater, a temperature display section, and the like.

As shown in FIG. 1, the front door 9 has a heat-resistant transparent glass 9R so that an operator can see the inside of the main body 2. The front door 9 is openably/closably held by hinge portions 9A and 9A. The front door 9 is closed in a sealed state with respect to the rectangular front opening 3B via door packing 3P. By pulling the handle of the front door 9 by the user, the front opening 3B of the front portion 3 can be opened in a single-opening type. The operator opens and closes the front door 9 to put an object in and out of the main body 2.

Next, a preferable structural example of the main body 2 will be described with reference to FIGS. 1 and 2.

As shown in FIGS. 1 and 2, the main body 2 includes a processing tank 10 and a base 10M. The processing tank 10 has a rectangular parallelepiped accommodating portion 11 inside. The housing portion 11 is a space surrounded by the front door 9 of the front surface portion 3, the back surface portion 4, the left side surface portion 5, the right side surface portion 6, the top surface portion 7, and the bottom surface portion 8. The front door 9, the back surface 4, the left side surface 5, the right side surface 6, the top surface 7, and the bottom surface 8 of the front surface 3 have a structure in which a heat insulating structure is arranged on a metal plate material such as stainless steel. The heat insulating structure is made of, for example, glass wool.

As shown in FIGS. 1 and 2, a heater 12 is arranged at the bottom of the housing 11. The heater 12 heats the air in the housing portion 12 by the energization from the control portion 100. The material of the heater 12 is, for example, a stainless pipe heater, but the material is not particularly limited. An example of the shape of the heater 12 is shown in FIG.

FIG. 3 is a horizontal schematic view of the natural convection dryer 1 shown in FIG. 1 taken along the line NN. As shown in FIGS. 1 and 3, the heater 12 is provided along a horizontal plane formed by the X direction and the Y direction at a distance from the inner surface 8F of the bottom surface portion 8. The heater 12 has a first end 13 and a second end 14. As shown in FIG. 2, the first end portion 13 and the second end portion 14 penetrate the bottom surface portion 8 and are led out to the outside of the bottom surface portion 8 and are electrically connected to the control unit 100.

As shown in FIG. 3, a curved first portion 15, a curved second portion 16, and a curved third portion 17 are provided between the first end portion 13 and the second end portion 14. .. Thereby, the heater 12 can radiate heat over a wide range of the inner surface 8F at a position apart from the inner surface 8F of the bottom surface portion 8.

Returning to FIG. 1 and FIG. 2, the bottom plate 20 is disposed at the bottom of the housing 11 and above the heater 12. The bottom plate 20 is provided along the horizontal plane formed by the X direction and the Y direction at a distance from the heater 12 by the support member 21 shown in FIG. Therefore, the heater 12 and the bottom plate 20 are arranged in parallel at the bottom of the housing 11.

No through hole is provided in the bottom plate 20. The bottom plate 20 can receive, for example, a liquid such as moisture falling from an object to be dried. The size of the bottom plate 20 is larger than the size of the heater 12, and the bottom plate 20 covers the heater 12 from above.

As shown in FIG. 1, the front side edge 22 of the bottom plate 20 is separated from the inner surface 9S of the front door 9, and similarly, the rear side edge 23 of the bottom plate 20 is connected to the inner surface 4S of the rear surface 4. Away from. Further, as shown in FIG. 2, the left side end 24 of the bottom plate 20 is separated from the inner surface 5S of the left side surface portion 5, and the right side end 25 of the bottom plate 20 is separated from the inner surface 6S of the right side surface portion 6. ing.

As described above, the front side end 22, the rear side end 23, the left side end 24, and the right side end 25 of the bottom plate 20 are connected to the front door 9 of the front part 3 and the rear part 4. The left side surface portion 5 and the right side surface portion 6 are separated from each other. Therefore, even if the bottom plate 20 is arranged above the heater 12, the natural convection of the air heated by the heater 12 can be raised so as not to be disturbed in the region below the bottom of the housing portion 11. ..

As shown in FIG. 1 and FIG. 2, the bottom surface portion 8 is provided with a plurality of intake ports 30 for taking in the outside air F into the accommodation portion 11. The outside air F is taken into the housing portion 11 from the intake port 30 and sent to the heater 12 side. FIG. 3 shows an example of the intake port 30, and the intake port 30 is provided with a circular lid 31. The lid 31 has a structure having a plurality of small holes 32. The number and shape of the intake ports 30 are not particularly limited to the illustrated example.

Next, the processing space SP for arranging an object will be described with reference to FIGS. 1 and 2.

The processing space SP is formed in the accommodation unit 11. The processing space SP is a rectangular parallelepiped space arranged above the bottom plate 20. The processing tank 10 includes a lowermost shelf 40 shown in FIGS. 1 and 2, a left partition 41 and a right partition 42 shown in FIG. 2, and a rear partition 43 shown in FIGS. There is. The processing space SP is formed by being surrounded by the lowermost shelf 40, the left partition 41, the right partition 42, and the rear partition 43. The partition wall is not arranged above the processing space SP but is open.

FIG. 4 is a horizontal schematic view taken along the line PP of the natural convection dryer 1 shown in FIG.

As shown in FIG. 4, the lowermost shelf 40 at the bottom is a square or rectangular plate member and extends along a horizontal plane formed in the X direction and the Y direction. The shelf 40 at the lowermost stage is designed to place a plurality of objects side by side when drying objects such as the containers and instruments used in the above-mentioned research.

As shown in FIG. 4, the lowermost shelf plate 40 has a plurality of through holes 40H over the entire surface. As a result, the outside air F taken in from the outside through the intake port 30 shown in FIGS. 1 and 2 is heated by the heater 12, and then, is heated from the lower region of the lowermost shelf 40 to the lowermost stage shown in FIG. It can be introduced into the processing space SP through the plurality of through holes 40H of the shelf board 40.

As shown in FIGS. 1 and 2, the left partition 41, the right partition 42, and the rear partition 43 are formed in the vertical direction (Z direction) from the lowest shelf 40. As shown in FIG. 1, the partition wall 43 on the rear surface side is provided so as to be parallel to the inner surface 4S of the rear surface portion 4 with a space C therebetween. Similarly, as shown in FIG. 2, the left partition wall 41 is provided so as to be parallel to the inner surface 5S of the left side surface portion 5 with a space D therebetween. The right partition wall 42 is provided so as to be parallel to the inner surface 6S of the right side surface portion 6 with a space D therebetween.

As shown in FIG. 1, by providing the space C, a back surface air flow path portion 51 is formed between the partition wall 43 on the back surface side and the inner surface 4S of the back surface portion 4 in the Z direction and the Y direction. The bottom plate 20 and the inner surface 7S of the upper surface portion 7 are formed along.

As shown in FIG. 2, by providing the spacing D, a left side air flow path portion 52 is formed between the left partition wall 41 and the inner surface 5S of the left side surface portion 5 in the Z direction and the X direction. It is formed along the surface from the bottom plate 20 to the inner surface 7S of the upper surface portion 7. Between the partition wall 42 on the right side and the inner surface 6S of the right side surface portion 6, a right side air flow path portion 53 is provided from the bottom plate 20 to the inner surface 7S of the upper surface portion 7 along a vertical surface formed by the Z direction and the X direction. Has been formed.

Further, as shown in FIGS. 1 and 2, an air path portion 60, which is below the bottom portion of the processing space SP, is formed between the bottom shelf plate 40 and the bottom plate 20. In the space below the bottom plate 20 in which the heater 17 is located, an air path portion 61, which is below the bottom of the processing space SP, is formed. The air path portion 61 is below the air path portion 60.

As shown in FIGS. 1 and 2, the lower portions of the back surface air flow path portion 51, the left side air flow path portion 52, and the right side air flow path portion 53 are respectively connected to the air path portion 60 of the lowermost shelf 40 and the air. It is connected to the route portion 61. As shown in FIGS. 1 and 2, the partition wall 41 on the left side has a plurality of side duct holes 66 in the air passage portion 60. Similarly, the partition wall 42 on the right side has a plurality of side surface duct holes 66 in the air passage portion 60. The plurality of side surface duct holes 66 allow the heated air to pass from the air passage portion 60 to the left side air passage portion 52 and the right side air passage portion 53.

Further, as shown in FIGS. 1 and 2, the air path portion 62 is formed along the horizontal plane formed in the X direction and the Y direction at the uppermost portion of the processing space SP. As shown in FIG. 1, on the inner surface 9S side of the front door 9, an air path portion 63 is formed along a vertical surface formed in the Y direction and the Z direction.

As illustrated in FIG. 1, the partition wall 41 on the left side is provided with a plurality of shelf board mounts 98 at equal intervals along the Z direction for hanging the shelf boards 99. Similarly, although not shown, a plurality of shelf boards 98 are provided on the right partition wall 42 for hanging the shelf boards 99. Accordingly, at least one shelf board 99 can be arranged so as to be hung on the shelf boards 98, 98 at an arbitrary height position in the processing space SP.

As shown in FIG. 1, a temperature sensor 70 for controlling the temperature inside the tank is provided at a lower portion of the lowermost shelf plate 40 and at an upper position near the bottom plate 20. Explaining an attachment example of the temperature sensor 70, the temperature sensor 70 is preferably arranged at a lower portion of the lowermost shelf 40 so that the temperature sensor 70 protrudes in the X direction with respect to the inner surface 4S of the rear surface portion 4. Are provided. However, the mounting method of the temperature sensor 70 is not particularly limited and can be arbitrarily selected.

The temperature sensor 70 is electrically connected to the control unit 100. The temperature sensor 70 is disposed below the bottom of the processing space SP of the main body 2, detects the temperature of the air heated by the heater 12 near the position of the heater 12, and outputs the temperature of the heater 12. It is used to adjust the amount of force and control the temperature in the processing space SP.

As the structure of the temperature sensor 70, for example, a sensor portion is passed through a SUS pipe having a diameter of 3 to 4 mm, and the tip portion of the pipe is designed so as not to affect the flow of heated air. It is roundly sealed.

As shown in FIGS. 1 and 2, the upper surface portion 7 is provided with a plurality of exhaust ports 80. As shown in FIG. 1, the exhaust port 80 is provided above the rear air flow passage portion 51 and at a position where the rear air flow passage portion 51 moves to the air passage portion 62.

FIG. 5 shows a structural example in the vicinity of the exhaust port 80. As shown in FIG. 5, the exhaust port 80 is provided with a lid 81, and the lid 81 is provided with a plurality of through holes 82.

Accordingly, the plurality of through holes 82 ensure the air permeability of the lid 81, so that the air can be exhausted even when the exhaust port 80 is closed by the lid 81. Further, when a large amount of exhaust gas is desired, the exhaust port 80 can be opened by sliding the lid 81 manually, for example, as necessary.

Next, with reference to FIG. 1 and FIG. 2, an example of use in drying an object by the above-mentioned natural convection dryer 1 will be described.

The operator opens the front door 9 shown in FIG. 1 and places an object on the shelf board 99 in the processing space SP or on the lowest shelf board 40. Then, the worker closes the front door 9 so that the front door 9 seals the front opening 3B.

The outside air F is sent to the heater 12 from the intake port 30. When the operator presses the start switch on the operation panel, the controller 100 shown in FIG. 1 energizes the heater 12 to heat the air around the heater 12 by the heat generated by the heater 12.

As shown in FIG. 1, the temperature sensor 70 detects the temperature of the air heated by the heater 12 in the vicinity of the heater 12 in the air path portion 60 which is the lower part of the shelf 40 at the lowermost stage. The temperature sensor 70 sends a temperature information signal RG relating to the temperature of the heated air around the heater 12 to the control unit 100. The control unit 100 adjusts the output amount of the heater 12 based on the temperature information signal RG of the temperature sensor 70 to control the temperature in the processing space SP and maintain the processing space SP at a predetermined temperature.

As described above, the temperature sensor 70 is arranged below the bottom of the processing space SP of the main body 2, and detects the temperature of the heated air around the heater 12. The temperature sensor 70 is installed below the lowermost shelf 40, and in addition, in the vicinity of the heater 12, a temperature information signal RG that early detects an increase in the temperature of the heated air around the heater 12 is output. It is sent to the control unit 100. Therefore, the control unit 100 can adjust the output amount of the heater 12 earlier according to the temperature information signal RG from the temperature sensor 12.

For this reason, the control unit 100 suppresses the surface temperature of the heater 12 located near the heater 12 at an early stage, so that the shelf board at the lowermost stage, which is a position below the bottom of the processing space SP of the main body unit 2. It is possible to reduce the temperature of the hot air of the heated air introduced into the processing space SP from the 40 side. Energy saving of the natural convection type dryer 1 can be achieved.

As shown by the arrow, the air G heated by the heater 12 shown in FIG. 1 passes through the air path portion 61 where the heater 17 is located, and reaches the rear side end portion 23 of the bottom plate 20 and the inner surface 4S of the rear surface portion 4. Then, the air G rises in the back surface air flow path portion 51 through the gap.

At the same time, as shown in FIG. 2, the air G heated by the heater 12 passes through the air path portion 61 in which the heater 17 is located and passes through the gap between the left side end portion 24 of the bottom plate 20 and the inner surface 5S of the left side surface portion 5. Ascending in the left side air flow path portion 52 through the side surface duct hole 66. At the same time, the air G heated by the heater 12 passes through the air passage portion 61 in which the heater 17 is provided, and passes through the side surface duct hole 66 from the gap between the right side end portion 25 of the bottom plate 20 and the inner surface 6S of the right side surface portion 6. And ascends in the right side air flow path portion 53. The heated air G that has risen in the left side air flow path portion 52 and the right side air flow path portion 53 passes through the passage 67 and flows into the air path portion 62 above the processing space SP.

As shown by the arrows in FIGS. 1 and 2, the heated air G that has risen in the back surface air flow path portion 51, the left side air flow path portion 52, and the right side air flow path portion 53 is at the upper part of the processing space SP. Part of the air G passes through the air path portion 62 of FIG. 1 and is discharged to the outside from the exhaust port 80 as shown in FIGS.

As shown in FIG. 1, the heated air G passes through the air passage portion 62 in the upper part of the processing space SP and descends in the air passage portion 63 along the inner surface of the front door 9 as shown by the arrow. It becomes H. The lowered air H flows into the air passage portion 60 as the air K.

The air K that has flowed into the air path portion 60 is sent back into the back surface air flow path portion 51, and the air K that has flowed into the air path portion 60 passes through the side surface duct holes 66 and becomes the left side air flow path portion 52. It is circulated by being sent into the right side air flow path portion 53. Moreover, the air K that has flowed into the air path portion 60 flows into the processing space SP through the plurality of through holes 40H shown in FIG.

The heated air G is moved up in the back surface air flow path portion 51, the left side air flow path portion 52, and the right side air flow path portion 53 in the processing tank 10, and the air K is raised in the accommodation space SP. Thus, it is possible to dry an object such as a container or an instrument placed on the shelf board 99 or the lowermost shelf board 40 and used for research.

As the first characteristic structure A of the natural convection dryer 1, the heated air G described above is generated by the back air flow passage portion 51 and the left side air flow passage portion 52 in the housing portion 11 of the processing tank 10. A natural convection type of air that is raised in the right side air flow path portion 53 is adopted, and the heated air G is circulated in the accommodation space SP of the accommodation portion 11.

For this reason, the rising temperature (air G) in the rear air flow path portion 51, which is generated when the rear surface side of the storage space S of the storage portion 11 of the processing tank 10 has the highest temperature and the inner surface 9S side of the front door 9 has the lowest temperature, is generated. ) And the ascending airflow (air G) in the left side air flow path 52 and the ascending airflow (air G) in the right side air flow path 53 and the descending airflow (air H) on the front door 9 side. I try to use it.

Therefore, the heat accumulation at the bottom of the lowermost shelf 40 that occurs when an object (also referred to as a sample) is erroneously spread over the lowermost shelf 40 over a specified area is The air can be released to the air flow path 51, the left side air flow path 52, and the right side air flow path 53.

In addition, as the second characteristic structure B of the natural convection dryer 1, as described above, the temperature sensor 40 is arranged below the bottom of the processing space SP of the main body 2, and the heater is used. A structure for detecting the temperature of the heated air around 12 is adopted. The temperature sensor 70 is installed below the lowermost shelf 40, and linearly detects the temperature rise of the heated air around the heater 12 and outputs the temperature information signal RG to the control unit 100. send. Therefore, the control unit 100 can adjust the output amount of the heater 12 earlier according to the temperature information signal RG from the temperature sensor 12.

The control unit 100 suppresses the surface temperature of the heater 12 located near the heater 12 at an early stage, so that the lowermost shelf 40 side, which is a position below the bottom of the processing space SP of the main body 2, is located. The temperature of the hot air introduced into the processing space SP in the tank is reduced.

The natural convection dryer 1 according to the embodiment of the present invention adopts the above-described first and second characteristic structures A and B, so that the temperature of the lower part of the lowermost shelf 40, that is, the heater 12 is reduced. Since it is possible to prevent the temperature of the surrounding heated air from becoming abnormally high with respect to the set temperature of the natural convection dryer 1 set by the control unit 100, the safety during the drying operation is improved. Can be improved.

By the way, in the structure of the natural convection dryer 1 illustrated in FIG. 1 and FIG. 2, all of the back surface air flow channel portion 51, the left side air flow channel portion 52, and the right side air flow channel portion 53 are used as the air flow channel portions. It is adopted.

However, the back surface air flow path portion 51 is provided on the back surface side of the processing space SP of the main body portion 2, or the left side air flow path portion 52 and the right side air flow path portion 53 are provided on the left and right side surfaces of the processing space SP of the main body portion 2. It is possible to arbitrarily select whether to provide each of them, or to combine all of the back surface air flow path portion 51, the left side air flow path portion 52, and the right side air flow path portion 53 as described above.

When a worker uses a normal natural convection dryer to dry the target object, the target shelf, such as a resin part, is laid over the shelf at the bottom of the dryer and the material is dried in the wrong way. Performing the work may lead to unexpected abnormal heating. The misuse of such natural convection dryers occurred at a constant rate every year.

However, by using the natural convection dryer 1 according to the embodiment of the present invention, it is possible to prevent unexpected abnormal heating on the lower side of the lowermost shelf 40, so that it is placed on the lowermost shelf 40. It is possible to prevent abnormal heating of the target object. That is, the back surface air flow path portion 51 is provided on the back surface side of the processing space SP of the main body portion 2, or the left side air flow path portion 52 and the right side air flow path portion 53 are provided on the left and right side surfaces of the processing space SP of the main body portion 2. Or by providing all of the back surface air flow path portion 51, the left side air flow path portion 52, and the right side air flow path portion 53 as described above, the lower shelf plate 40 is mistakenly provided. It is possible to prevent an abnormal temperature rise due to the stagnation of heat in the lower part of the lowermost shelf plate 40 that occurs when the objects are spread over the specified area.

As described above, the natural convection dryer 1 of the embodiment of the present invention is a natural convection dryer for accommodating and heating an object to dry it. This natural convection dryer 1 has a front opening 3B and a main body 2 having a processing space SP for accommodating and drying an object, and a front opening 3B of the main body 2 that can be opened and closed. Front door 9, a heater 12 arranged below the bottom of the processing space SP, and the air heated by the heater 12 is raised to heat the air heated to heat the processing space SP. For example, a back surface air flow passage portion 51 is provided as an air flow passage portion for convection in the main body portion.

As a result, in this natural convection dryer 1, for example, a rear air flow passage as an air flow passage portion that raises the air heated by the heater 12 to convect the air heated in the processing space in the main body portion 2. The unit 51 is provided. Therefore, for example, even when the object is spread over a predetermined area at the bottom of the processing space SP such as the lowermost shelf 40, the heat under the bottom of the processing space SP is reduced. It is possible to control the temperature of the processing space SP (the temperature in the bath) by preventing the accumulation.

Due to the stagnation of heat under the lowermost shelf plate 40, which occurs when the dried processed material which is the sample is erroneously spread over the bottom of the processing space SP such as the lowermost shelf plate 40 over a specified area. Abnormal temperature rise can be prevented by creating a natural flow of heated air by placing air ducts.

The air flow passage is a back air flow passage 51 provided on the back side of the processing space SP of the main body 2 on the side opposite to the front opening 3B. As a result, the temperature of the heated air is highest on the back side forming the processing space SP, and the temperature of the heated air is lowest on the front door 9 side forming the processing space. For this reason, for example, the back surface air flow path portion 51 as the air flow path portion is provided on the back surface side of the processing space SP of the main body portion 2 on the side opposite to the front surface opening portion 3B, so that the back surface side is heated. An updraft of air can be generated, and a downdraft of heated air can be generated on the front door 9 side. In this way, even when the heated air flow is created and the objects are spread over a predetermined area and arranged, it is possible to prevent heat accumulation under the bottom of the processing space SP.

The air channel portion is a rear air channel portion 51 provided on the back side of the processing space SP of the main body portion 2 on the side opposite to the front opening portion 3B, or the position of one side surface and the other side surface of the front opening portion 3B. That is, either the left side air flow path portion 52 and the right side air flow path portion 53 provided on one side surface and the other side surface side of the processing space SP of the main body portion 2, or one of the back surface side of the processing space and the processing space SP And on both sides of the other side.

As a result, the air flow path section generates an ascending air current of the heated air and a descending air current at the front door 9 side, thereby creating a flow of the heated air and setting a predetermined area. Even when the objects are spread and arranged as described above, it is possible to prevent the occurrence of heat accumulation under the bottom of the processing space SP.

The natural convection dryer 1 is disposed below the bottom of the processing space SP of the main body 2, detects the temperature of the air heated by the heater 12, and outputs a temperature information signal RG. It has a control unit 100 that controls the temperature in the processing space SP by adjusting the output amount of the heater 12 according to the temperature information signal RG from the temperature sensor 70.

As a result, the temperature sensor 70 is arranged at a position lower than the bottom of the processing space SP, detects the temperature of the air heated by the heater 12, and outputs the temperature information signal RG. The output amount of the heater 12 is adjusted by the information signal RG to control the temperature in the processing space. Therefore, the temperature sensor 70 can linearly detect an increase in the temperature of the air heated by the heater 12 at a position below the bottom of the processing space SP, and adjust the output amount of the heater early. Since the surface temperature of the heater 12 is suppressed at an early stage, the temperature of the hot air introduced into the processing space from the bottom of the processing space SP can be lowered. Further, energy saving of the natural convection dryer 1 can be achieved.

An exhaust port 80 communicating with the air flow path is provided in the upper portion of the main body part 2, and a lid 81 is arranged in the exhaust port 80, and the lid 81 has a through hole 81H for passing the exhaust gas. .. As a result, even when the exhaust port 80 is closed with the lid 81, exhaust can be performed through the through hole 81H. Since the lid 81 can open the exhaust port 80, the amount of exhaust can be increased when a large amount of exhaust is desired.

The back air flow passage portion 51, the left side air flow passage portion 52, and the right side air flow passage portion 53 as the air flow passage portions described above may be an air passage portion or an air duct portion through which air passes. Further, the back surface air flow path portion 51, the left side air flow path portion 52, and the right side air flow path portion 53 as the air flow path portion are formed on the inner surface of the main body portion 2 by using the flat partition walls 43, 41, 42. However, the partition wall is not limited to this, and may be a partition wall that is not flat, for example, a partition wall having a corrugated shape or the like in cross section.

Although the present invention has been described with reference to the embodiments, each embodiment is an example, and the scope of the invention described in the claims can be variously modified without departing from the scope of the invention. ..

For example, the arrangement position and the number of the exhaust ports 81 are not limited to the illustrated example, and can be arbitrarily selected. The shape of the heater 12 is not limited to the illustrated example, and can be arbitrarily selected. The front door 9 is a door that can be opened and closed by using a hinge, but may be opened and closed by a sliding type.

1 Natural Convection Dryer 2 Body 3B Front Opening (Example of Opening)
9 Front door (door)
12 Heater 40 Bottom shelf 51 Back air passage (example of air passage)
52 Air flow path on left side (example of air flow path)
53 Right side air passage (example of air passage)
60 Air path section (below bottom of processing space SP)
61 Air path section (below the bottom of the processing space SP)
80 Exhaust Port 81 Lid 81H Through-hole (hole) of Lid
100 control unit SP processing space RG temperature information signal

Claims (6)

A natural convection dryer for accommodating and heating an object to dry it,
While have a opening, a body portion having a treatment space for provided shelves, dried accommodates the object on top of the shelves,
A door that opens and closes the opening of the main body,
A bottom plate that constitutes the bottom part of the processing space below the bottom shelf plate, and forms an air path portion between the bottom shelf plate and the bottom plate,
A heater arranged at a position lower than the bottom plate ,
An air flow path section that raises the air heated by the heater to convect the heated air to heat the processing space in the main body section,
The air flow passage portion is a rear air flow passage portion provided on the back side of the processing space of the main body portion on the side opposite to the opening, and positions of one side surface and the other side surface of the opening portion. Consisting of the one side of the processing space of the main body part and the side air flow path part provided on the other side face side,
The air heated by the heater is raised from the back side air passage portion and the side air passage portion, the raised air is lowered from the opening side, and is formed between the bottom shelf plate and the bottom plate. A natural convection dryer, which is circulated through the air passage . The natural convection dryer according to claim 1, wherein a side surface duct hole is formed on a side surface of the main body portion in the air path portion . The natural convection dryer according to claim 1 or 2 , wherein a plurality of through holes are formed in the lowermost shelf plate . A temperature sensor that is arranged at a position lower than the bottom of the processing space of the main body, and outputs a temperature information signal by detecting the temperature of the air heated by the heater,
4. A control unit that controls the temperature in the processing space by adjusting the output amount of the heater according to the temperature information signal from the temperature sensor. A natural convection dryer described in Crab. An exhaust port communicating with the air flow path unit is provided in an upper portion of the main body unit, a lid is disposed at the exhaust port, and the lid has a hole for passing exhaust gas. The natural convection dryer according to any one of claims 1 to 4. The natural convection dryer according to claim 5, wherein the lid can open the exhaust port.

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