KR102037615B1 - Airflow formation mechanism in the weight loss and weight reduction processing apparatus and the weight loss and weight reduction processing apparatus - Google Patents

Abstract

Provided is a weight loss / reduction treatment apparatus that is downsized and excellent in handling, and an airflow formation mechanism employed in the weight loss / reduction treatment apparatus. An apparatus for reducing and reducing a workpiece by heating, comprising an accommodating container 2 and a heated air supply unit 10, wherein the heated air supply unit 10 includes a circulation unit 20 and a discharge unit. 30 and a suction part 40, the circulation part 20 includes a heating means 23 for heating the air flow flowing through the circulation flow path 21 and an air flow in the circulation flow path 21. The airflow forming means 22 is provided, and in the circulation flow path 21, a supply port for supplying air to the accommodation space 2 is formed on the inner surface of the container 2, and the suction portion ( The suction flow path 41 of 40 is formed so that the outflow port which is an opening of the accommodation space 2 side may adjoin a supply port.

Description

Airflow formation mechanism in the weight loss and weight reduction processing apparatus and the weight loss and weight reduction processing apparatus

This invention relates to the airflow formation mechanism in a weight loss and weight reduction apparatus and a weight loss and weight reduction treatment apparatus. More specifically, the present invention relates to a weight loss / reduction treatment apparatus capable of reducing and reducing waste containing water such as food waste, and an airflow forming mechanism in a weight loss / reduction treatment apparatus.

BACKGROUND ART Conventionally, in order to reduce the cost of disposing garbage generated at home or the like, a technique for reducing and reducing waste has been developed. If the waste can be reduced and reduced, the transportation cost and the combustion cost of the waste can be reduced, and the global warming gas can be reduced. In addition, the space for storing garbage at home can be reduced, and the storage period can be extended to a certain extent because the corruption is suppressed. This also provides an advantage that the number of waste discharges can be reduced.

For example, waste containing water, such as food waste discharged from home, may cause odor due to decay or the like during storage. In order to solve the said problem, the apparatus for drying the waste containing moisture is developed (patent document 1-4). By using this apparatus, it is possible to prevent the decay of the waste by contacting and drying the waste water containing the heated air, thereby preventing the occurrence of odor during storage. In addition, waste can be reduced and reduced by eliminating moisture. Therefore, by using the above apparatus, even waste containing water can be stored for a long time and the storage space can be reduced.

Japanese Unexamined Patent Publication No. 2008-290061 Japanese Utility Model Publication No. 04-110385 Japanese Patent Application Laid-Open No. 09-159358 Japanese Laid-Open Patent Publication 2001-25734 Japanese Patent Publication No. 4073487

In the apparatus described above, a case having a space for accommodating waste is provided, and all the devices are mounted in this case. One reason for this configuration is to prevent the odor from coming out of the waste when the waste such as food waste is heated, because the odor from the waste becomes stronger. In addition, although a blower for supplying heating air to the waste is provided, when all the equipment is enclosed in the case, it becomes easy to reduce the operation sound of the blower, the sound generated by the air flow caused by the blower, and the like. This is one reason.

However, since the device itself is enlarged by adopting the above-described configuration, when using it in a home or the like, a certain amount of space must be provided at the installation site of the device.

If the device is placed in a sink or the like and taken out only when used, the space occupied by the device may be prevented. However, since the apparatus includes all devices, the casing is enlarged and the weight is heavy. And since it is enlarged, the space for accommodating must be taken to some extent, and it is difficult to secure the place to accommodate.

In view of the above circumstances, an object of the present invention is to provide a weight loss / reduction treatment apparatus that is downsized and has excellent handling properties, and an airflow formation mechanism to be employed in the weight loss / reduction treatment apparatus.

A weight loss / reduction treatment apparatus according to the first aspect of the invention is an apparatus for reducing and reducing a workpiece by heating, wherein the accommodation container has an accommodation space for accommodating the workpiece with an opening at one end thereof, And a heating air supply unit detachably provided at the opening, wherein the heating air supply unit includes a circulation unit having a circulation passage for circulating air in the accommodation space, and a part of air flowing through the circulation passage of the circulation unit to the outside. A suction flow path which communicates between the discharge part to be discharged and the inner surface disposed in the housing container and the outer surface disposed outside the housing container in a state mounted in the opening of the housing container, and introduces outside air into the housing container. And a suction unit including a heating means for heating the air flow flowing through the circulation passage, and the circulation passage. The airflow forming means which forms an airflow is provided, In the said circulation flow path, The supply port which supplies air to the said accommodation space is formed in the inner surface arrange | positioned in the said accommodation container, The suction flow path of the said suction part is the said An inlet, which is an opening on the storage space side, is formed adjacent to the supply port.

In the weight loss / reduction processing apparatus of the second invention, in the first invention, the suction flow path of the suction part is provided so that the inlet port surrounds the periphery of the supply port.

In the weight loss / reduction processing apparatus of the third invention, in the first or second invention, the circulation flow path is provided such that the supply port is located at the center of the heating air supply unit, and the circulation flow path is connected to the supply port. A diffusion plate is provided.

In the weight loss / reduction treatment apparatus of the fourth invention, in the first, second, or third invention, the discharge portion communicates between a flow path downstream of the air flow forming means in the circulation flow path and the outside. The discharge flow path is provided, The discharge flow path is provided with a purification member accommodation space in which a purification member for purifying the discharged air is accommodated, and a deceleration space provided upstream of the purification member accommodation space. The cross-sectional area thereof is larger than the discharge passage on the upstream side of the deceleration space, and the discharge passage communicates with the axial direction of the outlet port through which air flows into the deceleration space, the deceleration space, and the purification member accommodating space. The axial direction of the communicating part is provided so that it may become a non-uniform axis | shaft. It is characterized by the above-mentioned.

The weight loss / reduction processing apparatus of the fifth invention includes a control unit for controlling the operation of the apparatus in the first, second or third invention, and the heating means includes the air flow forming means in the circulation portion. And a heating control unit provided on a downstream side of the control unit, the control unit including a heating control unit for ON-OFF operation of the heating unit in accordance with the temperature of air provided on an upstream side of the airflow forming unit, and being heated by the heating control unit. Based on the cycle of ON-OFF of a means, it is equipped with the operation stop function which determines the dry state of a to-be-processed object, and stops operation of a device.

The weight loss / treatment processing apparatus of the sixth invention includes a built-in case having an opening at one end and a through hole formed at a bottom thereof, which is disposed in the accommodation space, according to any one of the first to fifth inventions. The circulation flow path is provided such that the supply port is located at the center of the heating air supply unit, and the air flow forming means has a partition wall inserted into the opening of the interior case, and the partition wall is formed of the interior case. In the state inserted in the opening, the outer peripheral surface is formed so that it may be located in the vicinity of the opening inner surface of the said interior case.

In the weight loss / reduction processing apparatus of the seventh invention, in any one of the first to sixth inventions, the circulation flow path is provided such that the supply port is located at the center of the heating air supply unit, and is disposed in the accommodation space. And a built-in case having an opening at one end and a through-hole formed at the bottom, and having a low air permeability having low air permeability compared to the periphery in the vicinity of the center of the bottom.

The weight loss / reduction processing apparatus of the eighth invention has a built-in case having an opening at one end and a through hole formed at a bottom thereof, which is disposed in the accommodation space, according to any one of the first to seventh inventions. It is characterized by including a shaft-shaped portion to be installed standing on the bottom portion.

The weight loss / reduction processing apparatus of the ninth invention is the device according to any one of the first to eighth inventions, wherein the lower edge of the heating air supply unit attaches the heating air supply unit to the accommodation container. It is inclined with respect to a central axis, and has a control part which controls the operation | movement of the said heating means and / or the said airflow forming means, and the inclination detection part which detects the inclination of the said heating air supply part, The said control part is the said inclination detection part said When the inclination of the heating air supply portion is detected, it has an operation stop function for stopping the operation of the heating means and / or the air flow forming means.

In the ninth invention, the weight loss and reduction processing device according to the tenth aspect of the present invention is a device accommodation space in which the heating means and the air flow forming means are accommodated in the heating air supply part from an upstream side along an inclined direction of the lower edge. And arranged in the order of the discharge space in which the discharge portion is provided, wherein the purifying member is provided in the discharge space to purify the air to be discharged.

In the weight loss / reduction processing apparatus of the eleventh invention, in the ninth or tenth invention, the discharge portion is formed between the flow path downstream of the air flow forming means in the circulation flow path and the outside via the discharge space. A discharge flow path communicating with each other, the discharge flow path includes a purge member accommodation space in which the purge member is accommodated, and a deceleration space provided upstream of the purge member accommodation space, wherein the discharge flow path is the deceleration flow rate. A direction in which air flows into the space and a direction in which air flows into the purification member accommodation space from the deceleration space are provided so as to be non-coaxial.

In the ninth, tenth, or eleventh invention, the weight loss / reduction processing apparatus of the twelfth invention includes a built-in case having an opening at one end and a through hole formed at a bottom thereof, which is disposed in the accommodation space. The heating air supply part has an insertion part inserted into the said accommodating container when it is attached to the said accommodating container, The opening part formed in the lower end can accommodate the upper end of the said interior case inside It is characterized by being formed in size.

The weight loss / reduction treatment device of the thirteenth invention is a device for reducing and reducing a workpiece by heating air, and the device includes first, second, third, fourth, fifth, ninth, and fifth devices. It is comprised by the heating air supply part of description in 10 or 11th invention, It is characterized by the above-mentioned.

The airflow formation mechanism in the weight loss / reduction treatment apparatus of the fourteenth aspect of the invention is an airflow formation mechanism in an apparatus that reduces and reduces the object to be processed contained in the accommodation space by heating, and circulates air in the accommodation space. A circulation portion provided with a circulation flow passage and a suction portion provided with a suction flow passage communicating with the accommodation space and the outside and introducing outside air into the accommodation container, wherein the circulation portion is an air flow flowing through the circulation flow passage. Heating means for heating the air and air flow forming means for forming air flow in the circulation flow path, and the suction flow path of the suction portion includes an air inlet that is an opening on the storage space side. It is characterized in that it is formed adjacent to the supply port for supplying.

The airflow formation mechanism in the weight loss / reduction treatment apparatus of the fifteenth invention includes, in the fourteenth invention, a discharge portion for discharging a part of air flowing through the circulation flow path of the circulation portion to the outside, and the discharge portion is configured to perform the circulation. A discharge flow path communicating with a flow path on the downstream side of the air flow forming means in the flow path and the outside, wherein the discharge flow path includes a purge member accommodation space in which a purge member for purifying the discharged air is accommodated; A deceleration space provided on the upstream side of the purifying member accommodation space is formed, and the deceleration space has a cross-sectional area larger than that of the discharge passage on the upstream side than the deceleration space, and the discharge passage is in the deceleration space. The axial direction of the outlet port through which air flows in, and the axial direction of the communication part which communicates the said deceleration space and the said purification member accommodation space, have a non-uniform axis | shaft. It is characterized in that it is provided.

According to the first aspect of the invention, since the air in the storage container is circulated, the energy required for heating the air can be reduced. In addition, by discharging a part of the air flowing through the circulation passage from the discharge portion to the outside, the pressure in the accommodation space of the accommodation container can be reduced. Therefore, even if the heating air supply unit is detachably provided with respect to the accommodation container, it is possible to prevent odors and the like of the object to be leaked to the outside. In addition, the air flow blown out from the supply port of the circulation portion can increase the flow of outside air to the accommodation space through the suction flow path of the suction portion. Then, since the airflow forming means can be miniaturized, the noise of the apparatus can also be reduced. Furthermore, if the airflow forming means can be downsized, the apparatus including the heating air supply can be downsized. Moreover, since the heating air supply part is detachably provided with respect to the accommodating container, both can be stored separately. Then, compared with the case where the heating air supply part and the accommodation container are integrated, the space which accommodates an apparatus can be made small. In addition, since the weight can be reduced, the handleability can be improved.

According to the second aspect of the invention, since the flow of outside air directed to the accommodation space through the suction flow path of the suction portion can be effectively formed, the efficiency of introducing the outside air can be improved, and the drying effect can be enhanced.

According to the third aspect of the present invention, since the heated air can be supplied to the entire accommodation space of the accommodation container, the variation of the dry state of the workpiece can be suppressed, and the drying efficiency can also be improved.

According to the fourth aspect of the present invention, the flow rate of the air flowing into the purification member accommodation space can be slowed down, so that the entire purification member housed in the purification member accommodation space can be allowed to pass air. Then, since a purification member can be utilized effectively for purification | purification of air, efficiency, such as deodorization by a purification member, can be improved. Further, since the air can be made to pass through the entire purification member accommodating space evenly, the dead space of the purification member accommodating space is reduced, and longer life of the purification member can be achieved than simply allowing air to pass through.

According to the fifth aspect of the present invention, since the operation of the apparatus is stopped by detecting the dry state of the workpiece, the electric charge can be saved, and the workpiece can be dried efficiently. In addition, since the temperature of the workpiece is not directly measured, the configuration of the apparatus can be simplified.

According to the sixth aspect of the invention, since the heated air supplied from the supply port can be prevented from being circulated in a state in which it is not sufficiently in contact with the object, the object can be efficiently dried by the heated air.

According to the seventh aspect of the present invention, it is easy to supply heating air to an object to be disposed in the periphery of the built-in case, so that variation in the dry state of the object can be suppressed and the drying efficiency can be improved.

According to the eighth invention, it becomes easy to supply air into the stacked workpieces, so that drying of the workpieces can be promoted, and drying stains and insufficient drying can be prevented.

According to the ninth aspect of the invention, when the heating air supply part is placed on the floor or the like, the heating air supply part is inclined. When the inclination detection unit detects the inclination, the control unit stops the operation of the heating means and / or the air flow forming means. Therefore, after the reduction drying operation, it is possible to prevent forgetting to stop the heating means and / or the air flow forming means.

According to the tenth invention, stability in the case where the heated air supply unit is placed on the floor or the like can be increased.

According to the eleventh invention, since the flow velocity of the air flowing into the purifying member accommodation space can be slowed down, it is possible to allow air to pass through the entire purifying member accommodated in the purifying member accommodation space. Then, since a purification member can be utilized effectively for purification | purification of air, the efficiency of deodorization etc. by a purification member can be improved. In addition, since the air can be made to pass through the entire purification member accommodating space evenly, the dead space of the purification member accommodating space is reduced, and longer life of the purification member can be achieved than simply allowing the air to pass through.

According to the twelfth invention, since the lower edge of the insertion portion is inclined, when the tip portion is placed in the accommodation container, the heated air supply portion can be attached to the accommodation container. Therefore, the operation of attaching the heating air supply unit to the accommodation container becomes easy. In addition, when the heating air supply portion is attached to the housing container, the upper end of the built-in case can be accommodated in the insertion portion, so that the built-in case can be set to a predetermined position.

According to the thirteenth invention, when the apparatus is provided in an opening of a container in which a workpiece is placed, the workpiece in the container can be dried by heating air. In addition, since there is no need to provide a dedicated container, there is no need to move the object to be processed into a dedicated container. Therefore, the heat-drying process of a to-be-processed object can be made easy. In addition, since the apparatus is compact, the space for accommodating the apparatus can be reduced.

According to the fourteenth invention, the flow of outside air directed to the accommodation space through the suction flow path of the suction portion can be increased by the airflow blown out from the supply port of the circulation portion. Then, since the airflow forming means can be miniaturized, the noise of the apparatus can be reduced.

According to the fifteenth invention, the flow rate of air flowing into the purification member accommodation space can be slowed down, so that air can be made to pass through the entire purification member housed in the purification member accommodation space. Then, since a purification member can be utilized effectively for purification | purification of air, the efficiency of deodorization etc. by a purification member can be improved.

1: (A) is a schematic external perspective view of the weight loss reduction apparatus 1 of this embodiment, and (B) is a schematic plan view of the weight loss reduction apparatus 1 of this embodiment.
FIG. 2 is a cross-sectional view taken along the line II-II of FIG. 1 in the direction of the arrow, showing the appearance of the covers c1 and c2 of the circulation passage 21.
3 is a cross-sectional view taken along the line III-III of FIG.
4 is a cross-sectional view taken along the line IV-IV of FIG.
5 is a cross-sectional view of the VV line cross section in FIG.
FIG. 6 (A) is a view of the VIA-VIA line cross section of FIG. 3 viewed from the arrow direction, and (B) is a view of the VIB-VIB line cross section of FIG. 2 viewed from the arrow direction.
FIG. 7 (A) is a view of the VIIA-VIIA line cross section of FIG. 2 seen in the direction of an arrow, and (B) is a view of the VIIB-VIIB line cross section of FIG. 2 viewed from the arrow direction.
FIG. 8: is a schematic explanatory drawing of the weight loss reduction apparatus 1 of this embodiment which provided the diffusion plate 21p in the air inflow port 11h.
9 is a schematic explanatory view of a state in which the heating air supply unit 10 and the accommodation member 2 are separated.
FIG. 10: is a single view of the weight loss reduction processing apparatus which consists only of the heating air supply part 10, (A) is a side view, (B) is sectional drawing.
11 is a schematic external perspective view of the weight loss / treatment processing apparatus 1B of the present embodiment.
FIG. 12 (A) is a schematic plan view of the weight loss / treatment processing apparatus 1B of the present embodiment, and (B) is a single schematic bottom view of the heating air supply unit 60.
It is a figure which looked at the XIII-XIII line cross section of FIG. 12 (A) from arrow direction.
Fig. 14A is a view of the XIVA-XIVA line cross section in Fig. 13 as seen in the arrow direction, and (B) is a view of the XIVB-XIVB line cross section in Fig. 13 seen in the arrow direction.
FIG. 15 is a view of the cross section taken along the line XV-XV in FIG.
FIG. 16A is a schematic side view of the heating air supply unit 60, and FIG. 16B is a schematic front view of the heating air supply unit 60. FIG.
17 is a schematic schematic longitudinal sectional view of the heating air supply unit 60.
18 is an explanatory diagram of a state in which the heated air supply unit 60 is placed on the floor.

EMBODIMENT OF THE INVENTION Next, embodiment of this invention is described based on drawing.

The weight loss / reduction treatment apparatus of the present invention is a device for weight reduction and reduction of a workpiece, and the weight reduction and reduction of the workpiece is performed by bringing heated air into contact with the workpiece, and the apparatus can be miniaturized. It is characterized by reducing noise.

In addition, the to-be-processed object processed by the weight loss reduction apparatus of this invention is not specifically limited. For example, although food waste discharged from a home is mentioned, it is not limited to these.

(Schematic explanation of the weight loss and processing apparatus 1)

As shown in FIG. 1 and FIG. 2, the weight loss / treatment processing apparatus 1 of the present embodiment includes an accommodation container 2 that accommodates an object to be processed and heating that supplies heating air to the accommodation container 2. The air supply part 10 is provided.

Since the heating air supply part 10 is provided detachably with respect to the accommodating container 2 (refer FIG. 9), it can store them separately. Then, compared with the case where the heating air supply part 10 and the accommodating container 2 are integrated, the space which accommodates the weight loss reduction apparatus 1 of this embodiment can be made small. Moreover, since the weight reduction and the weight reduction processing apparatus 1 of this embodiment can also be reduced, handling property can be improved.

Hereinafter, each part is demonstrated.

(Accommodating container (2))

As shown in FIG. 9, the accommodation container 2 is a bottomed cylindrical member which has opening 2s at the upper end. This storage container 2 has a storage space 2h in which an object to be processed is accommodated, and the storage space 2h communicates with the outside by an opening 2s. Although the raw material of this accommodation container 2 is not specifically limited, What is necessary is just to be formed from the material which does not soften or deform | transform by the heating air supplied from the heating air supply part 10. As shown in FIG.

In addition, in FIG. 2, the internal case 51 is accommodated in the accommodation space 2h. When the inner case 51 is not used, the to-be-processed object is accommodated in the part where the inner case 51 is accommodated.

(Heated air supply unit 10)

As shown in FIG. 9, the heating air supply part 10 is provided in the opening of the accommodation container 2 so that attachment or detachment is possible. Specifically, when it is attached to the opening 2s of the storage container 2, the opening 2s can be blocked by the heating air supply part 10, and it becomes possible to block the space between the storage space 2h and the outside. have.

In addition, "it can cut off between the accommodation space 2h and the exterior" means that the state between the storage space 2h and the outside is airtightly blocked, and between the storage space 2h and the outside. In the concept of some degree of breathability, but including both of the state of the ventilation resistance is increased. As a latter state, the state in which the part in which the narrow gap is formed exists between the inner surface of the opening 2s of the accommodating container 2, and the outer surface of the heating air supply part 10 exists.

This heating air supply part 10 has the circulation part 20, the discharge part 30, and the suction part 40 in the main body case 11. As shown in FIG. The circulation section 20, the discharge section 30, and the suction section 40 are effectively arranged to provide heating air to the storage space 2h of the storage container 2 effectively while providing a compact structure. It is supposed to be. For example, as shown in FIG. 1 or FIG. 9, when the cross section of the weight loss / treatment processing apparatus 1 of this embodiment is circular, the diameter of the heating air supply part 10 may be 150-300 mm, and height may be set. It may be 100-200 mm, and it can form so that the height which attached the heating air supply part 10 to the accommodating container 2 may be about 200-400 mm. And if the weight loss reduction apparatus 1 of this embodiment is the size mentioned above, it becomes possible to process to-be-processed object up to about 5 liters. That is, the weight reduction and reduction processing apparatus 1 of this embodiment can be made into the magnitude | size of about 1/2-2/3 compared with the conventional apparatus which processes the to-be-processed object of the same quantity.

(Circulation part 20)

As shown in FIG. 3, the circulation portion 20 has a circulation flow passage 21 for circulating air in the accommodation space 2h of the accommodation container 2. In this circulation flow path 21, the airflow formation means 22 which produces the flow of air in the circulation flow path 21, and the heating means 23 which heat the air which flows in the circulation flow path 21 are provided.

For this reason, when the airflow forming means 22 is operated, the air in the accommodation space 2h of the accommodation container 2 is sucked into the circulation flow path 21. The air sucked in is heated by the heating means 23 while the inside of the circulation flow path 21 flows into heating air. And since heated air is returned from the circulation flow path 21 to the accommodating space 2h of the accommodating container 2 again, the to-be-processed object in the accommodating space 2h can be heated and dried by this heating air.

3 and 6 (A), the surface facing the inner bottom surface of the storage container 2 in the main body case 11 of the heating air supply unit 10 (hereinafter, The air inlet 11h and the outlet 21g are formed in the bottom face 11b of the main body case 11. That is, the air inlet 11h and the outlet 21g are formed in the bottom face 11b of the main body case 11.

The air inlet 11h is an opening for supplying heated air into the housing space 2h of the housing container 2, and is formed almost at the center of the bottom surface 11b of the main body case 11 (FIG. 6A). ) Reference). The circulation flow path 21 has the cylindrical frame 21f extended from this air inflow port 11h toward the outer surface of the main body case 11. Specifically, the lower end of the cylindrical frame 21f is connected to the bottom plate 11p of the main body case 11 so as to surround the air inlet 11h. In addition, the space inside the cylindrical frame 21f may be called the supply flow path 21a of the circulation flow path 21 which supplies heating air into the accommodation space 2h of the storage container 2 in some cases.

In this cylindrical frame 21f (that is, in the supply flow path 21a), the airflow forming means 22 and the heating means 23 from the outer surface side of the main body case 11 toward the bottom surface 11b side. These are listed in this order.

The airflow forming means 22 is arranged so as to form an airflow directed from the outer surface side of the main body case 11 to the bottom surface 11b side (that is, the airflow directed to the accommodation space 2h of the accommodation container 2). have. Although a general fan, a blower, etc. can be used for this airflow forming means 22, It will not specifically limit, if it is an apparatus which can form the above airflow. Moreover, the operation | movement of this airflow formation means 22 is controlled by the control part (it is built in the heating air supply part 10) which is not shown in figure.

In addition, the heating means 23 heats the airflow formed by the airflow forming means 22. Although a general electric heater etc. can be used for the heating means 23, as long as it can heat the said airflow, it does not specifically limit. In addition, operation | movement of the heating means 23 is controlled by the heating control part of the control part which is not shown in figure.

On the other hand, the discharge port 21g is an opening that sucks air in the accommodation space 2h of the accommodation container 2 into the circulation flow path 21. In other words, it is an opening which discharges the air in the accommodation space 2h of the accommodation container 2 to the circulation flow path 21. The discharge port 21g is formed of a plurality of through holes arranged along the periphery of the heated air supply unit 10. That is, the some through hole of 21 g of discharge ports is arrange | positioned so that the circumference | surroundings of the supply port 21a mentioned above may be enclosed (refer FIG. 6 (A)).

The circulation flow path 21 is provided with the return flow path 21b which communicates between the some through-hole of the discharge port 21g, and the inside of the cylindrical frame 21f. This return flow path 21b is provided with the covering part 21c and the ventilation part 21d. The covering part 21c is formed of the cover member c1 provided so as to cover the plurality of through holes of the discharge port 21g and the bottom plate 11p of the main body case 11. The ventilation part 21d communicates between the covering part 21c and the space (upper space) of the outer surface side of the main body part 11 from the airflow forming means 22 in the inside of the cylindrical frame 21f. It is prepared to. This vent 21d is formed of the outer surface of the cylindrical frame 21f and the cover member c2 provided to cover the outer surface. This cover member c2 is provided so that it may cover to the upper end of 21 f of cylindrical frames. That is, the circulation flow path 21 is provided so that the cylindrical frame 21f may be accommodated in the return flow path 21b (refer FIG. 3).

(Discharge part 30)

4, the heating air supply part 10 is equipped with the discharge part 30. As shown in FIG. This discharge part 30 is provided with the discharge flow path 31 which communicates between 21 f of cylindrical frames, and the exterior. This discharge flow path 31 communicates with the space (lower space) on the storage space 2h side of the storage container 2 and the outside from the airflow forming means 22 in the cylindrical frame 21f. It is prepared. Specifically, in the cylindrical frame 21f, a part of the airflow directed to the storage space 2h of the storage container 2 can be discharged to the outside through the discharge flow passage 31 of the discharge portion 30. It is. The discharge flow path 31 of this discharge part 30 surrounds the outer surface of the cover member c2 between the outer surface of the cover member c2 of the ventilation part 21d and the inner surface of the main body case 11. It has the purification member 35 arrange | positioned. Then, air is discharged through the purifying member 35.

(Suction part 40)

2, 4, and 5, the heating air supply part 10 is equipped with the suction part 40. As shown in FIG. This suction part 40 is provided in order to replenish the air discharged | emitted by the discharge part 30 to the outside. This suction part 40 is provided with the suction flow path 41 which communicates between the exterior and the inside of 21 f of cylindrical frames. This suction flow path 41 is a normal flow path 42 which communicates between the suction port 41a provided in the outer surface of the heating air supply part 10, and the upper space of the cylindrical frame 21f, The acceleration flow path 43 which communicates between the suction port 41a and the lower space of the cylindrical frame 21f is provided.

Specifically, the cover member 44 which covers the upper end of the cover member c2 is provided in the upper part of the cover member c2 of the ventilation part 21d, and this cover member 44 covers the cover member c2. The top of the is covered. The suction port 41a which introduces external air is provided in the side surface of this lid member 44. On the other hand, in the center part of the upper end of the cover member c2, the space between the upper end and the lid member 44 (inflow space 41h) and the space inside the cover member c2 (upper part of the cylindrical frame 21f) A flow path communicating with the space), that is, a normal flow path 42 is formed. In addition, this normal flow path 42 may be formed by a simple through-hole, or may be formed by a cylindrical member.

Moreover, a pair of through-holes g and g are provided in the periphery part of the upper end of the cover member c2 separately from the normal flow path 42 (refer FIG. 4, FIG. 7 (B)). The pair of through holes g and g communicate with the lower space of the cylindrical frame 21f via the pair of connection flow paths 43b and 43b, respectively. Specifically, the inside of the cover member c2 flows through the air drawn from the accommodation space 2h of the storage container 2 through the discharge port 21g (vent 21d of the return flow path 21b). A pair of connection flow paths 43b and 43b separated from each other are provided. These pair of connection flow paths 43b and 43b are arrange | positioned so that the cylindrical frame 21f may be interposed therebetween. The tubular frame 21f is provided with a plurality of through holes h that communicate the pair of connection flow paths 43b and 43b with the lower space of the cylindrical frame 21f. Specifically, two through holes h are provided in each connection flow path 43b, respectively.

At the positions where the plurality of through holes h are provided, the separating walls 43w are provided to separate the inside of the lower space of the cylindrical frame 21f into a space different from the spaces around the plurality of through holes h. . That is, in the lower space of the cylindrical frame 21f, a plurality of outflow passages 43c surrounded by the separating wall 43w and the inner surface of the cylindrical frame 21f are formed. The lower end of each of the separating walls 43w extends to the vicinity of the lower end of the cylindrical frame 21f. That is, the acceleration flow path 43 is formed by the pair of through holes g and g, the pair of connection flow paths 43b and 43b, the plurality of through holes h, and the plurality of outflow paths 43c. It is. And the lower end opening (corresponding to the inflow port mentioned in a claim) in the acceleration flow path 43 is arrange | positioned so that the center of the air inflow port 11h may be enclosed. In other words, the opening (patent frame 21f) of the flow path (cylindrical frame 21f) for supplying heating gas into the accommodation space 2h of the accommodation container 2 through the air inlet 11h through the position of the heating means 23 The lower end opening (corresponding to the inlet described in the claims) of the outlet passage 43c is disposed around and near the supply port referred to in the claims.

Since the airflow forming means 22 of the heating air supply part 10 is operated because it has the above structures, it is possible to generate airflow from the cylindrical frame 21f to the storage space 2h of the storage container 2. The air stream can be supplied to the storage space 2h of the storage container 2 after the air flow is heated by the heating means 23.

On the other hand, by the operation of the airflow forming means 22, the upper space of the cylindrical frame 21f is in a state of low air pressure. Then, in the return flow path 21b, the flow from the discharge port 21g toward the upper space of the cylindrical frame 21f is formed. That is, the air in the storage space 2h of the storage container 2 is in the state which is attracted to the upper space of the cylindrical frame 21f.

Therefore, by operating the airflow forming means 22, it is possible to circulate the air in the accommodation space 2h of the accommodation container 2. Then, since the air in the accommodation space 2h of the storage container 2, ie, heating air, is circulated, the energy required for heating the air can be reduced.

In addition, when the air inlet 11h and the outlet 21g are provided as described above, the flow of air in the storage space 2h of the storage container 2 is controlled by the storage space 2h of the storage container 2. It can be approximated by the flow of axisymmetry about the central axis. Then, since heated air can be made to contact substantially uniformly with the to-be-processed object in the accommodation space 2h of the accommodating container 2, the dispersion | variation in the dry state of a to-be-processed object can be suppressed.

Moreover, since some heating air circulating through the circulation flow path 21 is discharged | emitted by the discharge part 30, the pressure in the accommodation space 2h of the accommodation container 2 can be reduced. Therefore, even if the heating air supply part 10 is detachably provided with respect to the accommodating container, the odor of a to-be-processed object etc. can be prevented from leaking to the outside.

In addition, a part of the heating air circulating in the circulation passage 21 is discharged by the discharge portion 30, while outside air is introduced from the outside through the suction portion 40. Then, since the gas which became high in contact with the to-be-processed object and circulating heating air can be replaced with the low humidity outside air, drying efficiency can be improved.

In addition, the outside air sucked by the suction part 40 is sucked from the outside by the negative pressure generated by the airflow forming means 22 of the circulation part 20. Then, since it is not necessary to provide a special fan or the like for introducing outside air into the suction unit 40, the device can be miniaturized and energy can be saved.

Here, when only the airflow forming means 22 forms the airflow flowing through the circulation flow passage 21 and introduces the outside air through the suction flow passage 41 of the suction portion 40, the airflow forming means 22 is enlarged. Sometimes you have to. However, in the weight loss / reduction treatment apparatus 1 of the present embodiment, since the acceleration flow path 43 is disposed as described above in addition to the normal flow path 42 as the suction part 40, the air flow forming means 22. ), It is possible to efficiently introduce outside air without increasing the size.

As shown to FIG. 4 and FIG. 5, the inflow port 43 is located in the vicinity of the supply port of the cylindrical frame 21f of the circulation flow path 21. As shown in FIG. For this reason, when heating air flows into the accommodation space 2h of the accommodation container 2 from the supply port of 21 f of tubular frames, the outflow passage of the acceleration flow path 43 will arise from the flow of the heating air. The air (outside air) flowing from the lower end opening of 43c) can be increased. In addition, since the amount of air supplied from the circulation passage 21 to the accommodation space 2h of the accommodation container 2 can be increased, compared to the capacity of the airflow formation means 22, the airflow formation means 22 can be miniaturized. can do. And when the airflow formation means 22 is downsized, the sound and vibration which the airflow formation means 22 generate | occur | produce can also be reduced, and therefore the noise of the weight loss / reduction processing apparatus 1 of this embodiment can also be reduced.

In addition, by providing the acceleration flow path 43, the outside air of low humidity can be brought into contact with the workpiece with little contact with the heating air. Then, drying of the to-be-processed object can be accelerated | stimulated compared with the case where only heating air contacts a to-be-processed object.

In addition, since the heating air is circulated by the circulation flow path 21 of the circulation part 20 in the weight loss and reduction processing apparatus 1 of this embodiment, the airflow forming means 22 is exposed to high temperature air. Will remain. However, by supplying the outside air into the cylindrical frame 21f normally through the flow path 42, the airflow forming means 22 can also be brought into contact with air (outside air) of relatively low temperature. Therefore, damage to the airflow forming means 22 by operating in a state exposed to hot air can also be suppressed.

In addition, the position which arrange | positions the inflow port of the acceleration flow path 43 does not need to be provided so that the supply port of the cylindrical frame 21f of the circulation flow path 21 may be enclosed. What is necessary is just to arrange | position in the position where the said function (function which accelerates external air) is exhibited. However, when it arrange | positions as mentioned above, since the dispersion | variation in the external air which contacts a to-be-processed object can be suppressed, the dispersion | variation in the dry state of a to-be-processed object can be suppressed.

In addition, you may arrange | position the inflow port of the acceleration flow path 43 so that the whole periphery of the supply port of the cylindrical frame 21f of the circulation flow path 21 may be enclosed. In this case, since the said function (function which speeds up external air) can be exhibited more effectively, the efficiency of an external air introduction can be improved, and a drying effect can be improved.

(About discharge part 30)

Although the discharge part 30 may discharge heating air as it is, it is preferable to discharge | emit to outside after passing through the purification member 35 as mentioned above. With such a configuration, when the object to be processed is processed by the apparatus, it is possible to suppress the deterioration of the environment around the apparatus. As the purification member 35, a well-known deodorant, the filter which removes the harmful component contained in air, an activated carbon, etc. can be used, for example.

And it is preferable to provide the following purification member accommodation spaces 34 in the discharge flow path 31 of the discharge part 30, and to arrange | position the purification member 35 in the purification member accommodation space 34 as follows. . With the above structure, the purifying member 35 can be effectively used for purifying air, as compared with the case where only the air to be discharged is simply passed through the purifying member 35. Then, the efficiency, such as deodorization by the purification member 35, can be improved. In addition, since the air can be made to pass through the whole of the purification member accommodation space 34 evenly, the dead space of the purification member accommodation space 34 is reduced, and the flow of the purification member 35 is reduced. Long lifespan is possible.

Hereinafter, an example of the discharge flow path 31 of the discharge part 30 is demonstrated.

As shown in FIG. 4, the discharge passage 31 is provided in the main body case 11. The discharge flow passage 31 is a space surrounded by the cover members c1 and c2 of the circulation flow passage 21, the side surfaces of the main body case 11, and the upper cover 12 provided around the cylindrical frame 21f. And a pair of communication flow paths 32 and 32 (see FIG. 3).

As long as the space around the cylindrical frame 21f mentioned above accommodates the purification member 35 of the discharge flow path 31 by a pair of separation plate 31a, 31a and the some separation plate 31b. It is separated into a pair of purifying member accommodation spaces 34 and 34 and a pair of deceleration spaces 33 and 33.

The pair of separation plates 31a and 31a connect the bottom plate 11p of the main body case 11 so as to connect between the cover member c2 of the circulation flow passage 21 and the side surface of the main body case 11. It is arranged approximately parallel to. The pair of separation plates 31a and 31a are arranged so that a space is formed between the end portions which face each other in the circumferential direction of the cylindrical frame 21f in both the separation plates 31a. Moreover, the separating plate 31b is provided between the upper end part 12 and the both ends of the circumferential direction of the cylindrical frame 21f in a pair of separating plate 31a, 31a, respectively. That is, a box-shaped space surrounded by the separating plate 31a, the pair of separating plates 31b and 31b, the cover member c2 of the circulation flow passage 21, and the side surface of the main body case 11 is formed. have. The pair of box-shaped spaces constitutes a pair of purifying member accommodation spaces 34 and 34. That is, a pair of purification member accommodation spaces 34 and 34 are formed around the cover member c2 of the circulation flow passage 21. The pair of separation plates 31b and 31b, the cover member c2 of the circulation flow path 21, and the side surface of the main body case 11 are not breathable among the wall surfaces constituting the purifying member accommodation space 34. . On the other hand, the part which forms each purification member accommodating space 34 in the upper cover 12, and the separating plate 31a have air permeability. For example, the through hole or the separation plate 31a of the upper cover 12 has a through hole or is formed in a mesh shape. That is, in each purification member accommodation space 34, air can flow in the direction from the separating plate 31a toward the upper cover 12.

On the other hand, it is the deceleration space 33 except the part in which the purification member accommodation space 34 is formed among the said space around 21 f of cylindrical frames. This deceleration space 33 has a pair of upstream spaces 33a and 33a and a pair of downstream spaces 33b and 33b. Specifically, a pair of upstream spaces 33a and 33a are provided between the separating plates 31b and 31b of the other purification member accommodating spaces 34 that face each other. In addition, the pair of downstream spaces 33b and 33b are provided below the separating plate 31a.

The pair of spaces 33a and 33a in the deceleration space 33 communicate with the lower space of the cylindrical frame 21f by the pair of communication flow paths 32 and 32. These pair of communication flow paths 32 and 32 are all arrange | positioned so that the opening of one end of the lower space side of the cylindrical frame 21f may face the said airflow forming means 23. In addition, the other ends of the pair of communication flow paths 32 and 32 are arranged so that the openings thereof are in a state facing the side surface of the main body case 11.

Since the discharge flow path 31 has the above structure, a part of the air flow formed by the air flow forming means 23 is a pair of spaces in the deceleration space 33 via the pair of communication flow paths 32, 32. It flows into 33a, 33a. Air entered into the pair of spaces 33a and 33a is divided into the pair of downstream spaces 33b and 33b and the pair of purifying member accommodation spaces 34 and 34 from the pair of spaces 33a and 33a. Is discharged to the outside. That is, it can discharge to the outside via the purification member 35 in the pair of purification member accommodation spaces 34 and 34. FIG.

In addition, the cross-sectional area of the pair of spaces 33a and 33a is much larger than that of the pair of communication flow paths 32 and 32, and the pair of spaces 33a and 33a and the pair of downstream spaces 33b. , The volume of the deceleration space 33 including 33b is large. For this reason, the airflow which flowed into the pair of spaces 33a and 33a is decelerated when entering the pair of spaces 33a and 33a. Then, the speed at which air flows into the pair of purification member accommodation spaces 34 and 34 from the deceleration space 33 (that is, the pair of downstream spaces 33b and 33b) is also slowed down. Air can be made to pass through the whole purification member 35 accommodated in 34). That is, it is possible to prevent the air from escaping to a part of the purification member 35, such as when the inflow speed is high. Then, since the purification member 35 can be utilized effectively for purification | purification of air, the efficiency of deodorization etc. by the purification member 35 can be improved. In addition, since it is possible to allow air to pass through the entire purification member accommodation space 34 evenly, the dead space (area through which air does not pass) of the purification member accommodation space 34 is reduced, and the purification member 35 is simply provided. The life of the purification member 35 can be extended rather than allowing air to pass through it.

In particular, the direction (opening axial direction) of the other end opening of a pair of communication flow paths 32 and 32, and the direction which air flows into the purification member accommodation space 34 from the deceleration space 33 (namely, the claim The axial direction of the communication part which communicates with the purification member accommodation space in the range) is facing the other direction. That is, it is provided so that the flow direction of the air which flows into the purification member accommodation space 34 from the axial direction of the other end opening of the pair of communication flow paths 32 and 32 and the deceleration space 33 may be non-uniform. This can prevent the air introduced from the pair of communication flow paths 32 and 32 from being directly introduced into the purification member accommodation space 34, thereby preventing the air from escaping into a part of the purification member 35. It becomes easy to do it.

In the case where the deceleration space 33 is configured as described above, the axial direction of the other end openings of the pair of communication flow paths 32 and 32 is directed toward the side surface of the main body case 11 and upward of the inclination. It is more preferable if it arrange | positions so that it may become. In this arrangement, the air introduced into the pair of spaces 33a and 33a flows to the upper portion of the pair of spaces 33a and 33a even if there is a momentum flowing. That is, it is difficult to directly flow into the pair of purification member accommodation spaces 34 and 34 from the pair of communication flow paths 32 and 32 as well as the pair of downstream spaces 33b and 33b. Therefore, the flow velocity of the air which flows into the pair of purification member accommodation spaces 34 and 34 can be surely slowed down.

In the above example, the case where a pair of purification member accommodation spaces 34 is provided was demonstrated. However, one purifying member accommodation space 34 may be provided or three or more may be provided.

In addition, although the covering cover 13 is provided in the upper surface of the upper cover 12 in FIGS. 1-5, this covering cover 13 does not need to be provided. By providing the covering cover 13, since the flow of the discharged air can be suppressed, the contact efficiency of the purification member 35 and air in the purification member accommodation space 34 can be improved.

(About control part)

As described above, the weight loss / reduction processing device 1 of the present embodiment includes a control unit for controlling the operation of the device. This control part has a function of controlling the operation of the weight loss / reduction processing device 1 based on an input by an operation button or the like provided in the device. For example, it has a function which controls the operation | movement of the airflow formation means 22 and the heating means 23 corresponding to ON-OFF of a power supply. In addition, when there is an input by a timer, the airflow forming means 22 or the heating means 23 is operated for a predetermined time, or the airflow forming means 22 or the heating means 23 is turned off from the predetermined time. Operating to start the drying treatment of the object.

In particular, the control unit has a function (that is, a heating control unit) for stopping the operation of the apparatus, that is, the operation of the airflow forming means 22 or the heating means 23 when the dry state of the object to be processed becomes a predetermined state. desirable. The method by which this heating control part judges the dry state of a to-be-processed object is not specifically limited. For example, the sensor which contacts a to-be-processed object may be provided, and the dry state of a to-be-processed object may be judged directly. In addition, the humidity and / or temperature of the air in the storage space 2h of the storage container 2 and the humidity and / or temperature of the heating air flowing through the circulation flow path 21 are measured, and the dry state of the object to be processed is measured from the measured value. May be judged.

In addition, when the to-be-processed object is dried while maintaining heating air at predetermined temperature by ON-OFF control of the operation | movement of the heating means 23 by a heating control part, it does not directly measure the temperature of the to-be-processed object, The dry state of the processed material may be determined. For example, if a thermocouple or the like is provided upstream of the airflow forming means 22 (that is, the upper space inside the cylindrical frame 21f), the heating control unit operates the heating means 23 in accordance with the temperature of the air. ON-OFF. For example, the heating control part turns off the heating means 23 when the temperature of air exceeds a fixed temperature, and the heating control part turns on the heating means 23 when the temperature of air falls below a fixed temperature. In this case, if the ON-OFF cycle of the heating means 23 is grasped, the temperature of the to-be-processed object (namely, a dry state) can be estimated roughly, without measuring the temperature of a to-be-processed object directly. That is, since there is no need to provide a special sensor for measuring the temperature, the configuration of the device can be simplified.

The dry state can be grasped only by the ON-OFF cycle of the heating means 23 for the following reasons. First, when the to-be-processed object contains water, the heat of air is taken away in order to evaporate water. That is, by supplying the heat of vaporization to the to-be-processed object, the air returned from the accommodation space 2h is low in temperature, and the time of ON becomes long. On the other hand, as drying of a to-be-processed object progresses, since the heat of vaporization supplied to a to-be-processed object decreases, the temperature fall of the air returned from the accommodation space 2h is small. Therefore, the ON-OFF cycle of the heating means 23 becomes short. When the object to be processed is dried for a certain period or more, the heat of vaporization is no longer required, and thus the ON-OFF cycle is almost constant. Therefore, the ON-OFF cycle of the heating means 23 is shortened, and the operation of the apparatus is stopped when the ON-OFF cycle is made almost constant. Then, the operation of the apparatus can be stopped in a state where the object to be treated is properly dried, and the apparatus does not operate more than necessary, so that the electric charge can be saved and energy can be saved.

As a heating control part of the control part mentioned above, a bimetal thermostat, a humidity sensor, etc. can be employ | adopted, for example. Needless to say, not limited to these, of course.

(Diffusion plate)

In addition, when the air inlet 11h is arrange | positioned in the center of the heating air supply part 10, the to-be-processed object accommodated in the accommodating space 2h of the accommodating container 2 will be heated to the to-be-processed object located in the center part. Easy to feed. However, with respect to the to-be-processed object located in the periphery in the accommodation space 2h of the accommodation container 2, it is difficult to make heating air contact. Here, in order to make heating air contact uniformly with the whole to-be-processed object accommodated in the accommodation space 2h of the storage container 2, you may provide the diffuser plate which diffuses the flow of heated air in the air inflow port 11h.

For example, as shown in FIG. 8, the diffusion member 21p formed by combining board | plate material in a grid | lattice form is provided in the air inflow port 11h. The opening of the diffusion member 21p is formed so that the opening on the storage space 2h side of the housing container 2 is larger than the heating means 23. That is, the flow path formed between the plate members of the diffusion member 21p has a shape in which the cross section is widened toward the housing space 2h of the housing container 2. Then, it is possible to rectify the flow of the heating air to some extent, and to spread (spread) the flow. Then, since heated air can be supplied to the whole accommodation space 2h of the storage container 2, the dispersion | variation in the dry state of a to-be-processed object can be suppressed and drying efficiency can also be improved.

In addition, the structure of the diffusion member 21p should just be able to form the above-mentioned flow of heating air, and is not limited to the above shape. For example, it is also possible to use a porous plate or the like having a through hole formed so that the cross section is widened from one surface to the other surface as the diffusion member 21p.

(Built-in case 51)

As mentioned above, you may put the to-be-processed object into the storage container 2 as it is, and heat-dry. Also in this case, since the heating air supply part 10 can be removed from the storage container 2 in the weight loss and reduction processing apparatus 1 of this embodiment, cleaning of the storage container 2 etc. can be performed easily. . Moreover, the accommodating container 2 itself can be used like the trash container which puts into a to-be-processed object.

On the other hand, since the storage container 2 has a certain size, it is difficult to put it in the place where space is limited, such as a sink of a sink. Here, the built-in case 51 provided in the storage space 2h of the storage container 2 so that attachment or detachment is possible may be provided. In this case, if the built-in case 51 is formed to a size that can be installed in a sink or the like, the built-in case 51 containing waste such as a sink of a sink is simply put in the storage space 2h of the storage container 2, thereby removing waste. Can be processed. That is, since it is not necessary to transfer the waste (to-be-processed object) to the accommodation container 2, it becomes easy to process waste.

As the built-in case 51, for example, as shown in FIG. 4, the hollow part 51h which communicates with the outside by the upper opening 51s has inside, and the bottom part 51b is shown. A container having a plurality of through holes 51g can be used. When the built-in case 51 of such a shape is used, the heating air supplied from the air inlet 11h of the heating air supply part 10 can be introduce | transduced into the space 51h from the opening 51s. And the heating air which passed the to-be-processed object in the space 51h of the interior case 51 can be discharged | emitted from 51 g of the some through-holes of the bottom part 51b. Then, since heated air can be made to contact a to-be-processed object effectively, the process of a to-be-processed object by heated air can be performed effectively.

In addition, the built-in case 51 has a cross-sectional shape substantially similar to the storage space 2h of the storage container 2, and has a gap between the outer surface and the inner surface of the storage space 2h of the storage container 2. It is preferable that the shape is formed. In this case, the flow of the heating air in the storage space 2h of the storage container 2 can be approximated to the axisymmetric type centered on the central axis of the storage space 2h, so that the processing state of the object to be processed is uniform. It can be done.

Moreover, the leg part is provided in the bottom part of the built-in case 51. As shown in FIG. This leg part is provided in order to form the space for flowing heating air between the bottom part of the interior case 51 and the inner bottom face of the accommodation container 2. However, in the built-in case 51, when a hole for discharging the heating air is provided not on the bottom but on the side surface, the leg portion may not necessarily be provided.

(Configuration of Built-in Case 51)

When the air inlet 11h of the heating air supply part 10 is arrange | positioned in the center of the accommodating space 2h, it is difficult for air to permeate near the center of the bottom part 51b of the built-in case 51 (high ventilation resistance). It is desirable to provide a low ventilation section. For example, 51 g of through-holes formed in the bottom part 51b of the interior case 51 are small in the center part of the bottom part 51b (or 51 g of through-holes are made small, or 51 g of through-holes are provided). ), And increase (or increase) at the periphery. In this case, at the position of the opening 51s of the built-in case 51, the heated air supplied near the center of the built-in case 51 can flow from the vicinity of the center to the periphery while flowing toward the bottom 51b. have. Then, it becomes easy to supply heating air to the to-be-processed object located in the periphery of the built-in case 51, The dispersion | variation in the dry state of the to-be-processed object can be suppressed and drying efficiency can also be improved.

In the built-in case 51, an axial member extending from the bottom 51b toward the opening 51s may be provided. When the to-be-processed object is accommodated in the interior case 51, when the to-be-processed object is laminated | stacked and a density becomes high, the resistance at the time of a heating gas passing through a to-be-processed object will become large. Then, a heating gas flows only in the flow path with small resistance, and there exists a possibility that the deviation of the dry state of a to-be-processed object may become large. However, when the axial member is provided, a gap is formed around the axial member, so that the heating gas flows from the gap to the inside of the object. This makes it easier to supply air into the stacked workpieces, so that drying of the workpieces can be promoted, and drying stains and insufficient drying can be prevented.

In this case, the position, number, etc. which provide an axial member are not specifically limited. For example, only one axial member may be provided near the center of the bottom 51b, or a plurality of axial members may be provided concentrically from the central axis of the bottom 51b.

In addition, the cross-sectional shape of an axial member is not specifically limited. For example, it may be a cross section such as a circle or a star.

Although the length of an axial member is not specifically limited, either, The length of the grade which protrudes from the upper surface of the to-be-processed object which laminated | stacked is preferable.

In addition, the built-in case 51 may have a drip tray which mounts the built-in case 51. If the said water drip part is provided, even if the water | moisture content from the to-be-processed object in the interior case 51 is separated from the through-hole 51g, this water | moisture content can be kept in the drip part part. Then, it is possible to prevent the container 2 from being contaminated by moisture from the object to be treated.

(Division wall)

When providing the interior case 51 as mentioned above, the heating air supplied to the interior case 51 may flow along the surface (upper surface) of a to-be-processed object, without flowing into a to-be-processed object. Then, this heating air may be discharged | emitted from the discharge port of a circulation flow path through the clearance gap between the upper end of the built-in case 51, and the heating air supply part 10. FIG. That is, there is a possibility that the heated air is discharged from the storage container 2 without contributing to the drying of the workpiece.

3 to 5, when the built-in case 51 is provided, the partition wall 11w inserted into the opening 51s of the built-in case 51 is provided in the heated air supply part 10. You may provide. For example, the partition wall is arrange | positioned so that the air inlet 11h of the heating air supply part 10 may be enclosed. The dividing wall 11w is formed such that its tip is inserted into the interior case 51 and its outer diameter is located near the inner surface of the opening 51s of the interior case 51. If such a partition wall 11w is provided, the heating air supplied from the air inlet 11h will not escape from the clearance gap between the upper end of the built-in case 51 and the heating air supply part 10. FIG. As a result, the circulation of the heated air can be prevented from being in a state of not being in sufficient contact with the target object, so that the target object can be efficiently dried by the heated air.

(Other weight loss reduction processing apparatus 1B)

In the weight loss / reduction processing apparatus 1 described above, the cylindrical frame 21f of the circulation flow path 20 of the heating air supply unit 10 is disposed almost at the center of the heating air supply unit 10, and the heating air supply unit 10 is provided. The case where the air inlet 11h of the ()) is arrange | positioned in the substantially center of the bottom surface 11b of the main body case 11 was demonstrated.

However, the cylindrical frame 21f and the air inlet 11h of the circulation flow path 20 of the heated air supply unit 10 may not necessarily be disposed at the center of the main body case 11 or the bottom surface 11b. For example, it is good also as a structure similar to the weight loss reduction processing apparatus 1B shown below.

In addition, in the following description, the structure substantially common with the above-mentioned weight loss and reduction processing apparatus 1 is abbreviate | omitted suitably.

(Weight loss, processing apparatus 1B)

As shown in FIG. 11, the weight loss / reduction treatment apparatus 1B includes a heating air supply unit 60 and a storage container 2B.

(Heated air supply unit 60)

As shown in FIG. 13, the heating air supply part 60 of the weight loss / loss processing apparatus 1B is similar to the heating air supply part 10 of the weight loss / loss processing apparatus 1 mentioned above in the main body case 61. As shown in FIG. And a circulation portion 70, a discharge portion 80, and a suction portion 90. The heating air supply unit 60 has a more compact structure than the heating air supply unit 10 by studying the arrangement of the circulation unit 70, the discharge unit 80, and the suction unit 90.

(Accommodating container (2B))

The accommodating container 2B is a bottomed cylindrical container having an opening at an upper end similarly to the accommodating container 2 described above. This storage container 2B is comprised only by the part which accommodated the internal case 50. As shown in FIG. Specifically, in the storage container 2 of the weight loss / reduction processing apparatus 1, it was set as the shape which can insert the main body case 11 of the heating air supply part 10 in the upper part of the storage container 2. As shown in FIG. On the other hand, in the storage container 2B of the weight loss / reduction processing apparatus 1B, only the lower end of the heating air supply part 60 is inserted into the upper end opening of the storage container 2B. And the outer diameter of the upper end of the accommodating container 2B is formed so that it may become substantially the same size as the outer diameter of the main body case 61 of the heating air supply part 60. As shown in FIG. By setting it as the said structure, the height of the storage container 2 is low.

As described above, in the weight loss / reduction treatment apparatus 1B, both the heating air supply unit 60 and the storage container 2B are compact. Moreover, heating air is supplied to the to-be-processed object in the accommodating container 2B, with the heating air supply part 60 mounted in the upper end of the accommodating container 2B. For this reason, the weight loss reduction apparatus 1B can reduce the size of the whole apparatus compared with the weight loss reduction processing apparatus 1.

For example, as shown in FIG. 11 or FIG. 12, when the cross section of the weight loss / treatment processing apparatus 1B is circular, the diameter of the heating air supply part 60 is about 150-250 mm and height is 100-200 mm. And, the height in the state which attached the heating air supply part 60 to the accommodating container 2B can be formed so that it may become about 200-350 mm. And if the weight loss reduction apparatus 1B is formed in the size mentioned above, it becomes possible to process to-be-processed object up to about 12 liters.

(Heated air supply unit 60)

Hereinafter, each part of the heating air supply part 60 is demonstrated in detail.

(Circulation part 70)

As shown in FIG. 13, the circulation part 70 has the circulation flow path 71, and the airflow formation means 72 and the heating means 73 are provided in this circulation flow path 71. As shown in FIG.

Specifically, as shown in FIGS. 13 to 15, in the main body case 61 of the heated air supply unit 60, the heated air inlet 61h and the outlet port are provided at the bottom surface 61b of the main body case 61. 61g is formed. In addition, the air inlet 61s is formed near the heating air inlet 61h.

The heated air inlet 61h is an opening for supplying heated air into the storage space 2h of the housing container 2B, and is formed at a position biased from the center of the bottom surface 61b of the main body case 61 (Fig. 12 (B)). The circulation flow path 71 has the cylindrical frame 71f extended from this heating air inflow port 61h toward the outer surface of the main body case 11. Specifically, the lower end of the cylindrical frame 71f is connected to the bottom plate of the main body case 61 so as to surround the heating air inlet port 61h. And this cylindrical frame 71f is provided in the position which shifted to the one side of the line | part which divides the main body case 61 into two. That is, the cylindrical frame 71f is arrange | positioned in the area | region (corresponding to the apparatus accommodating space in a claim) of the one side of the line | part which divides main body case 61 into two. Moreover, the discharge part 80 mentioned later is arrange | positioned in the area | region on the opposite side to the area | region where the cylindrical frame 71f is arrange | positioned. The area where this discharge part 80 is arrange | positioned is corresponded to the discharge space in a claim.

In addition, the space inside the cylindrical frame 71f may be used as the supply flow path 71a of the circulation flow path 71 which supplies heating air into the accommodation space 2h of the storage container 2B.

In this cylindrical frame 71f (that is, in the supply flow path 71a), the airflow forming means 72 and the heating means 73 from the outer surface side of the main body case 61 toward the bottom surface 61b side. These are listed in this order. That is, similar to the airflow forming means 22 and the heating means 23 described above, the airflow forming means 72 forms an airflow directed to the accommodation space 2h of the storage container 2B, and then to the heating means 73. The airflow is heated so that the heated air can be supplied to the storage space 2h of the storage container 2B. In addition, operation | movement is controlled by the control part (it is built in the heating air supply part 60) which is not shown in the airflow formation means 22 and the heating means 23. As shown in FIG.

On the other hand, the discharge port 61g is an opening that sucks air in the accommodation space 2h of the accommodation container 2B into the circulation flow path 71. In other words, it is an opening which discharges the air in the accommodation space 2h of the accommodation container 2B to the circulation flow path 71. For example, in FIG. 12, although three discharge ports 61g are provided in the peripheral edge of the main body case 61, the number which provides 61g of discharge ports is not specifically limited.

The circulation flow path 71 is provided with the return flow path 71b which communicates between the discharge port 61g and the inside of the cylindrical frame 71f. This return flow path 71b is provided with the covering part 71c and the ventilation part 71d. The covering part 71c is formed of the cover member c3 provided so as to cover the plurality of through holes of the discharge port 61g and the bottom plate 61p of the main body case 61. The ventilation part 71d communicates between the covering part 71c and the space (upper space) of the outer surface side of the main body part 61 than the airflow forming means 72 in the cylindrical frame 71f. It is prepared to. This ventilation part 71d is formed of the outer surface of the cylindrical frame 71f, and the cover member c4 provided so that this outer surface may be covered. This cover member c4 is provided so as to cover the upper end of the cylindrical frame 71f. That is, the circulation flow path 71 is provided so that the cylindrical frame 71f may be accommodated in the return flow path 71b (refer FIG. 13, FIG. 15).

(Discharge part 80)

In addition, as shown in FIG. 13, the heating air supply part 60 is equipped with the discharge part 80. As shown in FIG. This discharge part 80 is provided with the discharge flow path 81 which communicates between the inside and outside of the cylindrical frame 71f. The discharge flow path 81 communicates with a space (lower space) on the storage space 2h side of the storage container 2B and the outside than the air flow forming means 72 in the cylindrical frame 71f. It is prepared. That is, in the cylindrical frame 71f, a part of the airflow directed to the storage space 2h of the storage container 2B can be discharged to the outside through the discharge flow path 81 of the discharge portion 80. .

(Suction part 90)

And, as shown in FIG. 13, FIG. 17, the heating air supply part 60 is equipped with the suction part 90. FIG. This suction part 90 is provided in order to replenish the air discharged | emitted by the discharge part 80 to the exterior. This suction part 90 is provided with the suction flow path 91 which communicates between the upper part of the main body case 61, and the outside air inlet 61s provided in the bottom surface 61b. This suction flow path 91 is provided between the outer wall of the main body case 61 and the cover member c4 of the ventilation portion 71d, and is formed to be in a state separated from the circulation flow path 71.

Since the air flow forming means 72 of the heating air supply part 60 is operated because it has the above structures, it is possible to generate the air flow directed from the cylindrical frame 71f to the storage space 2h of the storage container 2B. The air stream can be supplied by the heating means 73 to the storage space 2h of the storage container 2B.

On the other hand, by the operation of the airflow forming means 72, the upper space of the cylindrical frame 71f is in a state of low air pressure. Then, the flow from the discharge port 71g to the upper space of the cylindrical frame 71f is formed in the return flow path 71b. That is, the air in the storage space 2h of the storage container 2B is in the state which is attracted to the upper space of the cylindrical frame 71f.

Therefore, by operating the airflow forming means 72, it is possible to circulate the air in the containing space 2h of the containing container 2B. Then, since the air in the accommodation space 2h of the storage container 2B, ie, the heating air, is circulated, energy required for heating the air can be reduced.

Moreover, since some heating air which circulates through the circulation flow path 71 is discharged | emitted by the discharge part 80, the pressure in the accommodation space 2h of the accommodation container 2B can be decompressed. Therefore, even if the heating air supply part 60 is detachably provided with respect to the accommodating container, the odor of a to-be-processed object etc. can be prevented from leaking to the outside.

In addition, a part of the heating air circulating through the circulation passage 71 is discharged by the discharge portion 80, while outside air is introduced from the outside through the suction portion 90. Then, since the gas which became high in contact with the to-be-processed object and circulating heating air can be replaced with the low humidity outside air, drying efficiency can be improved.

In addition, the outside air sucked by the suction unit 90 is sucked from the outside by the negative pressure generated by the air flow forming unit 72 of the circulation unit 70. Then, since it is not necessary to provide a special fan or the like for introducing outside air into the suction unit 90, the device can be miniaturized and energy can be saved.

In addition, in the heating air supply part 60, the outside air inlet port 61s is formed in the vicinity of the heating air inlet port 61h. Then, since it contributes to the flow of the heated air supplied from the heating air inlet 61h to the accommodation space 2h of the accommodating part 2, and the introduction of external air from the suction part 90, it is possible to introduce external air efficiently.

And if the suction part 90 separated from the circulation flow path 71 is provided, the outside air with low humidity can be made to contact a to-be-processed object in the state with few contacts with heating air. Then, drying of the to-be-processed object can be accelerated | stimulated compared with the case where only heating air contacts a to-be-processed object.

In addition, since the heating air is circulated by the circulation flow path 71 of the circulation part 70 in the weight loss and reduction processing apparatus 1 of the present embodiment, the airflow forming means 72 is exposed to high temperature air. Will remain. However, as shown in FIG. 13, if the air flow introduction means 72s which communicates with the circulation flow path 71 and the exterior is provided separately from the suction part 90, the airflow formation means 72 will provide the air of comparatively low temperature ( Outside air). Therefore, the damage of the airflow forming means 72 by operating in the state exposed to hot air can also be suppressed.

Moreover, when providing 72s of external air introduction passages, the flow path diameter of 72s of external air introduction passages is made small. As a result, it is possible to prevent the outside air from being introduced from the outside air introduction passage 72s so that the outside air introduction effect from the suction unit 90 can be prevented from being lowered.

(About the discharge part 80)

Although the discharge part 80 may discharge heating air as it is, it is preferable to discharge | emit to the outside after passing through the purification member 85 as mentioned above. With the above configuration, when the object to be processed is processed by the apparatus, it is possible to suppress the deterioration of the environment around the apparatus. As the purification member 85, a well-known deodorant, the filter which removes the harmful component contained in air, etc. can be used, for example.

And it is preferable to provide the following purification member accommodation spaces 84 in the discharge flow path 81 of the discharge part 80, and to arrange | position the purification member 85 in the purification member accommodation space 84. . With the above configuration, the purifying member 85 can be effectively used for purifying air as compared with the case where only the air to be discharged is simply passed through the purifying member 85. Then, the efficiency, such as deodorization by the purification member 85, can be improved. In addition, since the air can be made to pass evenly with respect to the whole purification member accommodation space 84, the dead space etc. of the purification member accommodation space 84 are reduced, and rather than simply letting air flow through, Long lifespan is possible.

Hereinafter, an example of the discharge flow path 81 of the discharge part 80 is demonstrated.

As shown in FIG. 13 and FIG. 17, the discharge passage 81 is provided in the main body case 61. This discharge flow path 81 has a cylindrical frame 81f whose lower end is connected to the bottom plate of the main body case 61 (see FIG. 14 (A)). This cylindrical frame 81f is arrange | positioned on the opposite side to the cylindrical frame 71f with respect to the line which divides the main body case 61 into two.

This cylindrical frame 81f is equipped with the upper plate 81a in the upper end part, and is provided with the lower plate 81b in the position slightly spaced apart from the bottom plate below the upper plate 81a. The upper plate 81a and the lower plate 81b are both formed in the structure which has air permeability. For example, as shown in FIGS. 13 and 17, a plurality of through holes may be provided to have breathability, or a plurality of slits may be provided to have breathability. The purification member 85 is arrange | positioned between this upper plate 81a and the lower plate 81b. That is, the space between the upper plate 81a and the lower plate 81b is the purification member accommodation space 84.

On the other hand, the deceleration space 83 is formed between the purification member accommodation space 84 and the bottom plate 61p (refer FIG. 14). And the reduction part 82b of the communication flow path 82 is formed in the circumference | surroundings of the lower part of the cylindrical frame 81f so that the circumference | surroundings of the deceleration space 83 may be enclosed. This deceleration part 82b communicates with the deceleration space 83 by the opening s provided in the lower part of the cylindrical frame 81f.

Moreover, this deceleration part 82b is communicated with the lower space of the cylindrical frame 71f by the inflow part 82a of the communication flow path 82. This inflow part 82a is arrange | positioned so that the opening of one end of the lower space side of the cylindrical frame 71f may face the said airflow formation means 72. As shown in FIG. Moreover, the other end of the inflow part 82a is arrange | positioned so that the opening may be in the state toward the side of the cylindrical frame 81f.

Since the discharge flow path 81 has the above structure, a part of the air flow formed by the air flow forming means 72 passes through the inflow portion 82a and the deceleration portion 82b of the communication flow path 82. Flows into. The air which entered into the deceleration space 83 flows into the purification member accommodation space 84 from the reduction space 83, and is discharged to the outside through the purification member 85. That is, the purification member 85 can purify the air and discharge the purified air to the outside.

Here, the opening s which communicates the deceleration part 82b and the deceleration space 83 has the direction different from the direction which flows into the deceleration part 82b from the inflow part 82a. That is, the opening s is provided in the position which does not oppose the other end of the inflow part 82a. For example, as shown in FIG. 14, the opening s is provided in the position rotated 90 degrees from the center axis of the cylindrical frame 81f with respect to the position of the other end of the inflow part 82a. Then, the air which flowed in from the inflow part 82a into the speed reduction part 82b collides with the side surface of the cylindrical frame 81f, changes the direction of flow, and flows along the cylindrical frame 81f. Then, the flow direction is changed again at the position of the opening s and flows into the deceleration space 83. That is, the air flowing into the deceleration portion 82b from the inflow portion 82a is introduced into the deceleration space 83 after largely changing the direction of the flow at least twice, so that the speed is introduced at the stage introduced into the deceleration space 83. Is getting significantly slower. In addition, when flowing into the purification member accommodation space 84, the direction of the flow is changed again, so that the velocity of air flowing into the purification member 85 is slowed down. Can be. That is, it is possible to prevent the air from escaping to a part of the purification member 85 such as when the inflow speed is high. Then, since the purification member 85 can be utilized effectively for the purification | purification of air, the efficiency of deodorization etc. by the purification member 85 can be improved. In addition, since it is possible to allow air to pass through the entire purification member accommodation space 84 evenly, the dead space (area through which air does not pass) of the purification member accommodation space 84 is reduced, and the purification member 85 is simply provided. The life of the purification member 85 can be extended rather than allowing air to pass through it.

(About the bottom edge of the heated air supply part 60)

As shown in FIG. 16, the heating air supply part 60 is formed so that the lower edge may become inclined with respect to the central axis of the heating air supply part 60 when viewed from the side. In other words, the lower edge is inclined with respect to the central axis of the apparatus when the heating air supply unit 60 is attached to the accommodation container 2B.

Specifically, the main body case 61 of the heating air supply part 60 is provided with the leg member 61r standing up on the bottom plate 61p. This leg member 61r is provided so as to surround the heating air inflow port 61h provided in the bottom plate 61p, and is formed in substantially cylindrical shape. This leg member 61r is provided so that the center axis | shaft may become the same axis as the center axis of the main body case 61. As shown in FIG. And the lower edge 61e of the leg member 61r is provided so that the cylinder may be cut out to the cross section inclined with respect to the center axis. For example, the lower edge 61e of the leg member 61r is formed so that it may become in the state which inclined about 5-20 degrees with respect to the central axis of the heating air supply part 60. FIG.

(About control part)

The heated air supply unit 60 also includes a control unit for controlling the operation of the apparatus, similarly to the heated air supply unit 10. In addition to the function of the control part of the heating air supply part 10, this control part has the following functions.

The control part of the heating air supply part 60 is equipped with the inclination detection part. This inclination detection part has a function which transmits a signal when the central axis of the heating air supply part 60 inclines more than a predetermined angle with respect to a perpendicular direction. For example, it has a function which transmits a signal when the central axis of the heating air supply part 60 turns to 5 degrees or more with respect to a perpendicular direction. As described above, when the lower edge 61e of the leg member 61r is inclined by about 5 to 20 degrees with respect to the central axis of the heating air supply unit 60, the lower edge 61e of the leg member 61r is bottomed. When the heating air supply part 60 is placed in contact with each other, the central axis of the heating air supply part 60 is inclined by 5 ° or more with respect to the vertical direction (Fig. 18 (B)). Therefore, the inclination detection unit transmits a signal that the heating air supply unit 60 is inclined.

The control unit of the heating air supply unit 60 stops the operation of both or one of the airflow forming unit 72 and the heating unit 73 when the tilt detection unit sends a signal indicating that the heating air supply unit 60 is inclined. Has a stop function.

If the control part of the heating air supply part 60 has the function as mentioned above, after the persimmon drying operation by the heating air supply part 60 is complete | finished, the heating air supply part 60 may be removed from the accommodating container 2B, etc. In this case, the operation of the airflow forming means 72 or the heating means 73 can be stopped automatically. That is, even if it forgets to stop the operation | movement of the airflow formation means 72 and the heating means 73, and removes the heating air supply part 60 from the accommodating container 2B, and places it on the floor etc., the airflow formation means 72 and / or The heating means 73 can be stopped. If the air flow forming means 72 or the heating means 73 is placed on the floor or the like while operating, the bottom or the like may be heated by the heating air. However, by providing the function in the control section, the problem can be prevented from occurring.

Moreover, if the said function does not stop, especially the part enclosed by the leg member 61r will continue to be heated by heating air. In this case, when the notch g or the through hole is provided at the lower end of the leg member 61r, the heated air can be discharged to the outside, so that the above problem can be solved.

In addition, the inclination of the lower edge 61e of the leg member 61r may be inclined in any direction. However, in the state where the heating air supply part 60 is arrange | positioned so that the lower edge 61e of the leg member 61r may contact the floor, the perpendicular | vertical line which passes the center of gravity of the heating air supply part 60 may be a leg member in the floor etc. It is preferable to intersect the vicinity of the center of the space surrounded by 61r. By setting it as the above structure, when the heating air supply part 60 is made to contact the bottom edge 61e of the leg member 61r, the heating air supply part 60 can be arrange | positioned stably.

In particular, when the heating air supply unit 60 is placed on the floor or the like, it is arranged so as to be arranged in the order of the equipment accommodation space and the discharge space from the upstream side along the inclined direction of the lower edge 61e of the leg member 61r. Stability in can be made high.

Moreover, when the lower edge 61e of the leg member 61r is inclined, the front end (namely, the lowest end, the lower left end in FIG. 16 (A)) will be easily accommodated in the storage container 2B. That is, when the lower end 61e of the leg member 61r is put in the opening of the accommodating container 2B, and the heating air supply part 60 is lowered, the center of the heating air supply part 60 will naturally be the center of the accommodating container 2B. The posture is adjusted to fit the center of the. Therefore, the operation | work which installs the heating air supply part 60 in the accommodation container 2B becomes easy.

In addition, if the lower edge 61e of the leg member 61r is inclined, the front end is simply inserted into the gap between the inner surface of the housing container 2B and the outer surface of the inner case 50, so that the inner case 50 Can be positioned to a predetermined position. That is, the heating air supply part 60 is guided to the inner surface of the leg member 61r only by putting the heating air supply part 60 into the opening of the accommodating container 2B, and moving down, and the built-in case 50 is a leg member. It is housed inside 61r, and a predetermined position (for example, the central axis of the built-in case 50 coincides with the central axis of the heating air supply unit 60 (ie, the central axis of the housing container 2B)). Position)). That is, even if the built-in case 50 is placed in the containing container 2B without positioning, when the heating air supply unit 60 is provided in the containing container 2B in the same manner as described above, the built-in case 50 is automatically determined. Can be placed at the position of.

In addition, the leg member 61r has the same structure as that of the heating air supply unit 10 described above, in addition to the case where the heating means 73 is disposed in a biased position like the heating air supply unit 60 described above. It is also possible to employ.

(Cover plate (95))

The cover plate 95 is provided in the bottom surface 61b of the main body case 61 of the heating air supply part 60 mentioned above. This cover plate 95 is formed slightly smaller than the upper end opening of the interior case 50. In addition, the cover plate 95 is formed in such a state that the lower end thereof is almost the same height as the upper edge of the built-in case 50 in the state where it is attached to the bottom surface 61b of the main body case 61. In addition, the cover plate 95 is provided with a through hole 95h for allowing the heating air to pass through at a position corresponding to the heating air inlet 61h.

Therefore, even if the amount of the heated object accommodated in the inner case 50 is large and protrudes from the upper opening of the inner case 50, the heated object can be prevented from overflowing from the inner case 50. Can be.

(Other weight loss processing equipment)

The above-mentioned heating air supply part 10 and the heating air supply part 60 may be used as a weight loss / reduction processing apparatus independently (refer FIG. 10, FIG. 16). Also in this case, if a container for placing the object to be processed is separately provided and a weight loss / reduction treatment device (that is, a heating air supply unit 10 or a heating air supply unit 60) is provided in the opening, the The supplied heated air can be brought into contact with the workpiece in the container. Therefore, the to-be-processed object can be dried by heating air.

In this case, since there is no need to provide a dedicated container for placing the object, the object to be processed can be dried by providing a container for storing food waste or the like and providing a weight loss / reduction treatment device in the container. That is, when processing a to-be-processed object, it is not necessary to transfer a to-be-processed object to the exclusive container, and heat-drying process of a to-be-processed object becomes easy.

In addition, since the weight loss / treatment processing apparatus does not provide a dedicated container for placing the object to be processed, the weight loss / treatment processing apparatus itself can be made compact. Then, the space which accommodates a weight loss / treatment processing apparatus can be made small. For example, only the weight loss / reduction processing apparatus which consists only of the heating air supply part 10 and the heating air supply part 60 is stored in a storage shelf, etc., and the container which puts a to-be-processed object can be installed in a sink etc. Then, even when both the heating air supply part 10, the heating air supply part 60, and a container are stored, a storage space can be made small.

In addition, the weight loss / reduction processing apparatus including only the heated air supply unit 10 and the heated air supply unit 60 has a structure that circulates most of the air in the container, and also has a structure that sucks some air from the outside air. have. For this reason, the air in a container can be prevented from leaking outside as it is. Then, even if the to-be-processed object generate | occur | produces bad smell, such as food waste, it can prevent the odor leaking outside.

In addition, when installing the weight loss reduction apparatus which consists only of the heating air supply part 10 and the heating air supply part 60 in the opening of a container, the clearance gap between the outer surface of a weight loss reduction processing apparatus and the inner surface of a container is prevented. You may provide a sealing member. Providing a seal member can more reliably prevent the air in the container from leaking to the outside.

(Other air flow forming mechanism)

Moreover, you may provide the airflow formation mechanism of the heating air supply part 10 and the heating air supply part 60 mentioned above to another weight loss reduction processing apparatus, a food dryer, a food dryer, a dish dryer, etc. In this case, in a weight loss / reduction treatment apparatus or the like provided with an airflow formation mechanism, air can be circulated by the circulation portion, and by the airflow blown out from the supply port of the circulation portion, the air flows through the suction flow path of the suction portion to the accommodation space. Can increase the flow of air to the outside. Then, since the weight reduction / reduction processing apparatus etc. which provided the airflow formation mechanism can be miniaturized, the noise of a weight reduction / reduction processing apparatus etc. can be reduced.

Similarly, when a discharge part such as the heated air supply part 10 or the heated air supply part 60 is provided, the flow rate of the air flowing into the purifying member accommodating space can be slowed down. You can let air through. Then, since a purification member can be utilized effectively for purification | purification of air, the efficiency of deodorization etc. by a purification member can be improved.

The weight loss / treatment processing apparatus of the present invention is suitable as an apparatus for drying a processed object having moisture such as food waste.

1: Weight loss, processing device
2: receiving container
2h: accommodation space
10: heating air supply
20: circulation
21: circulation flow path
22: airflow forming means
23: heating means
30: discharge part
31: suction path
33: deceleration space
34: purification member accommodation space
35: purifying member
40: suction part
41: suction path
51: built-in case
60: heating air supply
70: circulation
71: circulation flow path
72: air flow forming means
73: heating means
80: discharge part
81: suction path
83: deceleration space
84: purification member accommodation space
85: purifying member
90: suction part
91: suction path

Claims (15)

As a device for reducing and reducing the processed object by heating,
An accommodating container having an accommodating space accommodating the object to be processed having an opening at one end thereof;
It is provided with the heating air supply part detachably provided in the opening of the said accommodation container,
The heating air supply unit,
A circulation portion having a circulation flow path for circulating air in the accommodation space;
A discharge part for discharging a part of the air flowing in the circulation flow path of the circulation part to the outside;
In the state mounted in the opening of the said container, the suction part provided with the suction flow path which communicates between the inner surface arrange | positioned in the said container and the outer surface arrange | positioned outside the said accommodation container, and introduces external air into the said accommodation container. Doing
The circulation portion,
Heating means for heating the air flow flowing in the circulation passage;
Airflow forming means for forming airflow in the circulation flow path,
In the circulation passage, a supply port for supplying air to the accommodation space is formed on the inner surface disposed in the accommodation container,
The suction flow path of the suction unit,
An inflow port, which is an opening on the side of the accommodation space, is formed to be adjacent to the supply port. The method of claim 1,
The suction flow path of the suction unit,
The said inflow port is provided so that the circumference | surroundings of the said supply port may be provided. The method according to claim 1 or 2,
The circulation passage,
The supply port is provided so as to be located in the center of the heating air supply,
The circulation passage,
The said feed port is provided with the diffusion plate, The weight loss and processing apparatus characterized by the above-mentioned. The method of claim 1,
The discharge portion,
And a discharge flow path communicating between the flow path on the downstream side of the air flow forming means and the outside in the circulation flow path,
In the discharge passage,
A purifying member accommodation space containing a purifying member for purifying the discharged air;
The deceleration space provided in the upstream of the said purification member accommodation space is formed,
The deceleration space,
The cross-sectional area is larger than the discharge passage on the upstream side of the deceleration space,
The discharge passage,
The axial direction of the outlet port through which air flows into the said deceleration space, and the axial direction of the communicating part which communicates the said deceleration space and the said purification member accommodation space are provided so that it may become non-uniaxial. Device. The method of claim 1,
It is provided with a control unit for controlling the operation of the device,
The heating means,
In the said circulation part, it is provided in the downstream of the said airflow forming means,
The control unit,
It is provided with the heating control part which controls ON-OFF operation | movement of the said heating means according to the temperature of the air upstream of the said airflow forming means,
And an operation stop function for stopping the operation of the apparatus by judging the dry state of the object to be processed based on the cycle of ON-OFF of the heating means by the heating control unit. The method of claim 1,
A built-in case having an opening at one end and a through hole formed at a bottom thereof, disposed in the accommodation space,
The circulation passage,
The supply port is provided so as to be located in the center of the heating air supply,
The air flow forming means,
And a partition wall inserted into the opening of the built-in case,
The partition wall,
In the state inserted into the opening of the said interior case, the outer peripheral surface is formed so that it may be located in the vicinity of the opening inner surface of the said interior case, The weight loss reduction apparatus characterized by the above-mentioned. The method of claim 1,
The circulation flow path is provided such that the supply port is located at the center of the heating air supply unit.
A built-in case having an opening at one end and a through hole formed at a bottom thereof, disposed in the accommodation space,
A weight loss / reduction treatment apparatus characterized by including a low ventilation portion having a lower air permeability than a peripheral portion in the vicinity of the center of the bottom portion. The method of claim 1,
A built-in case having an opening at one end and a through hole formed at a bottom thereof, disposed in the accommodation space,
A reduction and reduction processing apparatus, comprising: an axial portion that stands on the bottom and is provided. The method of claim 1,
The heating air supply unit,
The lower edge is inclined with respect to the central axis of the apparatus when the heating air supply unit is attached to the housing container,
A control unit for controlling the operation of the heating means and the air flow forming means or the heating means or the air flow forming means;
An inclination detection unit for detecting an inclination of the heating air supply unit,
The control unit,
The tilt detection unit has an operation stop function for stopping the operation of the heating means and the air flow forming means or the heating means or the air flow forming means when detecting the inclination of the heating air supply portion. Processing unit. The method of claim 9,
The heating air supply unit,
Along the inclined direction of the lower edge, they are arranged side by side from the upstream side in the order of an apparatus accommodating space in which the heating means and the air flow forming means are accommodated, and a discharging space in which the discharging portion is provided.
In the discharge space,
A purifying member for purifying the air to be discharged is provided. The method of claim 9,
The discharge portion,
And a discharge flow path communicating with the outside of the flow path on the downstream side of the air flow forming means in the circulation flow path through the discharge space.
In the discharge passage,
A purging member accommodation space in which the purifying member is accommodated,
The deceleration space provided in the upstream of the said purification member accommodation space is formed,
The discharge passage,
And a direction in which air flows into said deceleration space and a direction in which air flows from said deceleration space into said purifying member accommodation space are provided to be non-uniaxial. The method of claim 9,
A built-in case having an opening at one end and a through hole formed at a bottom thereof, disposed in the accommodation space,
The heating air supply unit,
When attached to the said container, it is equipped with the insertion part inserted into the said container,
The insertion unit,
The lower end opening is formed in the magnitude | size which can accommodate the upper end of the said interior case inside, The weight loss reduction processing apparatus characterized by the above-mentioned. As a device for reducing and reducing the object to be processed by heating air,
That device,
It is comprised by the heating air supply part of Claim 1, The weight loss and processing apparatus characterized by the above-mentioned. As airflow formation mechanism in the apparatus which reduces and reduces the to-be-processed object accommodated in the accommodation space by heating,
A circulation portion having a circulation flow path for circulating air in the accommodation space;
A suction part provided with a suction flow path which communicates between the accommodation space and the outside and introduces outside air into the accommodation container,
The circulation portion,
Heating means for heating the air flow flowing in the circulation passage;
Airflow forming means for forming airflow in the circulation flow path,
The suction flow path of the suction unit,
An inflow port, which is an opening on the side of the accommodation space, is formed to be adjacent to a supply port for supplying air to the accommodation space in the circulation flow path. The airflow formation mechanism according to the weight loss / reduction treatment apparatus. The method of claim 14,
And a discharge part for discharging a part of the air flowing in the circulation flow path of the circulation part to the outside,
The discharge portion,
And a discharge flow path communicating between the flow path on the downstream side of the air flow forming means and the outside in the circulation flow path,
In the discharge passage,
A purifying member accommodation space containing a purifying member for purifying the discharged air;
The deceleration space provided in the upstream of the said purification member accommodation space is formed,
The deceleration space,
The cross-sectional area is larger than the discharge passage on the upstream side of the deceleration space,
The discharge passage,
An axial direction of an outlet through which air flows into the deceleration space, and an axial direction of a communication portion communicating with the deceleration space and the purifying member accommodating space are provided so as to be non-coaxial. Airflow forming apparatus.

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