KR101611715B1 - The drying system of mass warehouse - Google Patents

Abstract

The present invention relates to a system for drying a large amount of material in a warehouse, characterized in that it comprises a supply duct for blowing / circulating air heated by a heat source to the inside of the warehouse, A central drying unit having a discharge duct for discharging the air to the outside; An auxiliary drying unit having a rail connected to the warehouse in a predetermined direction and having an operation unit moving in a direction set in engagement with the rail; A sensing unit having a position sensor for sensing a position on a rail of the auxiliary drying unit and a temperature sensor for sensing a room temperature on the operation unit; And a control unit for feedback-controlling the operation according to a set value that is connected to the central drying unit, the auxiliary drying unit, and the sensing unit in a circuit manner.
Accordingly, it is an object of the present invention to provide a method and apparatus for drying a large amount of material uniformly under the same condition through an auxiliary drying unit which can be moved in each compartment along with a central drying unit, There is an effect that can be.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drying system for mass storage,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drying system for a warehouse, and more particularly, to a drying system for a large-capacity warehouse capable of storing and drying a large amount of materials such as agriculture, aquatic products, textiles, foods,

Generally, agriculture, aquatic products, textiles, food, and processed parts are subjected to a drying process with a certain moisture content before shipment. In particular, agriculture, aquatic products, food and textiles are essential for long-term storage. That is, a medium / small size dryer having the most suitable structure on a process line for manufacturing a material is disposed and dried in specific conditions suitable for the characteristics of the material, and then distributed to consumers.

In recent years, due to the development of technology, many automation equipments have been equipped, and the production speed is rapidly increasing with the production speed. However, the equipment for drying the produced material has a limited storage space, and due to the nature of the material, there is a limit in that it can not be dried at a high temperature unconditionally for rapid drying. In addition, there is a problem in that moisture is reabsorbed in the course of distribution and long-term storage of already dried and shipped materials. Therefore, development is urgently needed to solve these problems.

According to Korean Patent Registration No. 10-1226451 entitled " Bidirectional dehumidification and drying system for a large warehouse ", a drying room 10 of a large warehouse 1 and a drying room 10 of a large warehouse 10 are arranged in a ceiling 20 of the large warehouse 10 And a dehumidifying and drying unit 30 for blowing dehumidified high temperature air into the drying chamber 10. The drying chamber 10 has a shutter 30 extending upward from the bottom of the drying chamber 10 to the ceiling 20, And a first and second drying chambers 11 and 13 partitioned by a plurality of drying chambers 15 and a duct 21 in which the drying and drying device 30 is installed are provided in the ceiling 20, The drying units (43,53) include an indoor condenser (220,230) or a heater in a refrigeration cycle, and the blowing units (45,55) include driving motors (46,56) and driving motors , Wherein the ceiling (20) is provided with a blower fan (47, 57) which is rotated by an air inlet A bypass duct 31 for guiding the air in the drying chamber 10 between the drying units 43 and 53 and the air supply units 45 and 55 is formed in the bypass duct 31. In the bypass duct 31, And a damper (33) that is opened and closed to adjust the amount of air flowing into the dehumidifying chamber (31).

The drying system suggests that a large warehouse is divided and the agricultural products can be uniformly dried by blowing in two-sided type. However, in order to substantially dry a large warehouse, it is necessary to have a system with thermal efficiency corresponding to the space. Of course, by blowing in both directions, the circulation power can be better than the simple type, but it is not enough to dry a large amount of materials at the same time. First of all, there is a serious case that if a large quantity of material is not put in one at a time and it is put in a sequential order for a predetermined period, it will affect the material that is pre-ordered.

Korean Patent Registration No. 10-1226451 entitled "Two-way dehumidification drying system of a large warehouse"

Accordingly, it is an object of the present invention to fundamentally solve the above-described problems of the prior art, and it is an object of the present invention to provide a method and apparatus for drying a large amount of materials uniformly under the same conditions, The present invention has been made in view of the above problems, and it is an object of the present invention to provide a large-capacity warehouse drying system capable of storing various materials at the same time.

In order to achieve the above object, the present invention provides a system for drying a large amount of material in a warehouse, the system comprising: a supply duct for blowing / circulating air heated by a heat source to the inside of the warehouse; A central drying unit having a discharge duct for discharging the air to the outside; An auxiliary drying unit having a rail connected to the warehouse in a predetermined direction and having an operation unit moving in a direction set in engagement with the rail; A sensing unit having a position sensor for sensing a position on a rail of the auxiliary drying unit and a temperature sensor for sensing a room temperature on the operation unit; And a controller for feedback-controlling the operation according to a set value that is connected to the central drying unit, the auxiliary drying unit, and the sensing unit in a circuit manner.

At this time, the heat source of the central drying unit according to the present invention is characterized in that either the fossil energy using electricity, gas, petroleum or the natural energy collected by the solar heat-absorbing plate is used either singly or in combination of two or more .

Further, the rails of the auxiliary drying unit according to the present invention are characterized by having one of a straight shape, a cross shape, and a corrugated shape depending on the material arranged in the warehouse.

The operation unit of the auxiliary drying unit according to the present invention may further include a driving wheel that rotates in engagement with the rail at both ends of the frame, a feed motor connected to the driving wheel to apply a moving force, And a pivoting motor connected to the pivot shaft for imparting a pivoting force to the pivot shaft.

The sensing unit may further include a camera for measuring the surface temperature of the material on the operation unit and photographing the outer shape in real time.

At this time, the operation unit according to the present invention further includes a protection net for protecting the material from the blowing fan and blocking the inflow of foreign matter to the outer periphery of the frame.

In addition, the operation unit according to the present invention further includes a heater for heating the air by receiving a heat source in the protection net.

The control unit may further include a terminal connected to the server by wire or wirelessly and transmitting a setting value while outputting information, wherein the terminal transmits information transmitted from the control unit through a graphic, a document and a barcode And D / B is made so that the consumer can inquire the history of the material from the wired and wireless.

It should be understood, however, that the terminology or words of the present specification and claims should not be construed in an ordinary sense or in a dictionary, and that the inventors shall not be limited to the concept of a term It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

As described above, the present invention provides the following effects.

First, it is possible to uniformly dry a large amount of material under the same conditions through the subsidiary drying part which can be moved by each compartment together with the central drying part, and it is possible to dry various materials in different conditions at the same time.

Second, it can automatically determine whether there is a breakdown or an accident, so that emergency recovery and coping of situation can be taken quickly, thus improving overall construction and preventing various accidents in advance.

Third, while real-time monitoring and control from outside can be supported remotely, purchase history can be inquired by both buyer and seller, thus high reliability and excellent quality can be expected.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a drying system according to the present invention. FIG.
Fig. 2 to Fig. 4 are schematic views showing a drying system according to the present invention in a plan view. Fig.
5 is a perspective view showing the main part of the drying system according to the present invention.
6 is a perspective view showing a main part according to a modification of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a system for drying a large amount of material 5 in a warehouse 1 and comprises a central drying unit 10, an auxiliary drying unit 20, a sensing unit 30 and a control unit 40 And a drying system for large-capacity warehouses. The drying system of the present invention is dried based on the central drying unit 10 and the auxiliary drying unit 20 serves as the central drying unit 10 to dry a large amount of the material 5 uniformly and in various conditions To be able to do so. At this time, in order to dry a large amount of the material 5, it is limited to the large warehouse 1, but it is limited to the warehouse 1 having a volume area of 100 square meters (330 square meters) or more.

The central drying unit 10 according to the present invention includes a supply duct 11 for blowing / circulating air heated by a heat source to the inside of the warehouse 1, And a discharge duct (15) for discharging the gas. The central drying unit 10 is installed on the ceiling of the warehouse 1 as shown in FIG. 1, and heats the internal air by an external heat source to dry the material 5. [

The supply duct 11 is branched from the ceiling of the warehouse 1 in both directions and the discharge duct 15 is provided at the upper center of the supply duct 11 so as to communicate with the outside. The supply duct 11 and the exhaust duct 15 are provided with blowing fans 11a and 15a for blowing in or outside air, respectively, and are provided with opening and closing plates for selectively opening and closing the flow channels. Here, the supply duct 11 is provided with a heat dissipating unit 11b which is heated by a heat source in front of the blowing fan 11a.

That is, when the blowing fan 11a is operated, air is forcibly blown to the heat radiating unit 11b, and the blown air is heated while passing through the heat radiating unit 11b heated by the heat source. The heated air is gathered from both sides of the warehouse 1 to the center, and during this process, moisture is evaporated through the material 5 stored in the warehouse 1. The air containing moisture and the poorly discharged air passes through the blowing fan 15a of the exhaust duct 15 and is discharged to the outside.

At this time, the heat source of the central drying unit 10 according to the present invention may be selected from either fossil energy using electricity, gas, petroleum, or natural energy collected by a solar heat absorbing plate, or use two or more of them in parallel. The heat source supplies heat energy to the heat dissipating unit 11b, and the energy required to dry a large amount of the material 5 is considerable. Therefore, it is desirable to combine fossil energy and natural energy together. In this case, it is preferable that the heat dissipating unit 11b is formed of a radiator so that heat exchange from fossil energy and natural energy is possible. Of course, the heat dissipating unit 11b may be independently configured so that it can be used for fossil energy use and natural energy use.

The auxiliary drying unit 20 according to the present invention includes an operation unit having a rail 21 connected to the warehouse 1 in a predetermined direction and moving in a direction in which the rail 21 is engaged with the rail 21. The auxiliary drying unit 20 is installed on the ceiling of the warehouse 1 immediately below the central drying unit 10 to dry the material 5 more efficiently with the central drying unit 10 as shown in FIG.

The rail 21 guides the operation unit to be movable in a predetermined direction and the operation unit controls the air heated by the central drying unit 10 to be supplied to the specific material 5 through the centralized blowing, . Here, the rail 21 has one of a straight shape, a cross shape, and a waveform depending on the material 5 partitioned in the warehouse 1.

As shown in FIG. 2, the straight lines are formed across the center of the warehouse 1, and the cross lines are formed in left and right and up and down directions as shown in FIG. 3, and the waveforms are formed in a zigzag shape as shown in FIG. For example, it is preferable that the flat type is applied to the case where the size of the volume-contrast material 5 of the warehouse 1 is large and the drying rate is high. It is also preferable that the cruciform shape is applied to the case where the size of the volume-contrast material 5 of the warehouse 1 is relatively small and the drying rate is low. It is also preferable that the waveform is applied to a case where the volume of the material 5 in the warehouse 1 is very small and the materials are sequentially entered and discharged.

Here, the drying rate refers to the drying temperature and time required as a percentage of the moisture content. These rails 21 may be applied in consideration of the respective characteristics of the material 5 in addition to the size of the material 5 and the drying rate.

Meanwhile, when the rail 21 is formed into a cross shape, it further includes an actuator for selectively switching the connection direction. This configuration is the same as that of converting a line of a general train, so detailed description and drawings are omitted.

The operation unit includes a drive wheel 24 that rotates in engagement with the rail 21 at both ends of the frame 23, a feed motor 25 that is connected to the drive wheel 24 to apply a movement force, A rotating fan 26 mounted on the rotary table 26 for blowing air and a rotary fan 26 connected to the rotary table 26 for imparting a rotary force to the rotary table 26, (28).

The frame 23 is formed to have a width and a height corresponding to the rail 21 and the warehouse 1. The frame 23 has a rectangular frame (plane reference) that is seated on the rail 21, And a rectangular frame (front surface reference) extending so as to be adjacent to the bottom of the frame. The driving wheel 24 is axially connected to both ends of the square frame and rotates along the rail 21 and the feeding motor 25 is connected to the driving wheel 24 in the square frame to transmit the moving force to the set position do. The rotary table 26 is coupled to the upper and lower ends of the rectangular frame by an axis, and the rotary motor 28 is connected to the upper rotary shaft by a worm gear to transmit the rotary force in the setting direction. Here, at least one blowing fan 27 is provided on the pivot 26 to blow indoor air according to the setting direction.

At this time, the operation unit further includes a protection net 29 which protects the material 5 from the blowing fan 27 and blocks the inflow of foreign matter to the outer periphery of the frame 23. [ The protection net 29 is surrounded to enclose the rectangular frame of the above-described frame 23 as shown in Fig. The protection net 29 safely protects the worker as well as the material 5 from the blowing fan 27. Above all, foreign substances contained in the air are prevented from flowing and passing through, thereby increasing the service life of the air blowing fan 27 while blowing clean air on the material 5. Here, it is preferable that the protection net 29 is basically formed of a metal wire net, and the fiber net is covered with a dense fiber net according to the material 5. [

In addition, the operation unit according to the present invention further includes a heater 29a that receives a heat source and heats the air in the protection net 29. Although not shown in detail in the drawing, the heater 29a is configured in the same manner as the heat dissipating unit 11b described above. That is, it may be constituted by a heater pipe in accordance with the aforementioned heat source, or may be constituted by a radiator or a combustion chamber. The heater 29a generates heat to dry only the specific material 5 stored in the warehouse 1 intensively.

Since the operation unit can be moved in the warehouse 1 as described above, a large amount of material can be dried uniformly under the same conditions, and it can be dried under different conditions for each material, so that various materials can be stored at the same time.

The sensing unit 30 according to the present invention includes a position sensor 31 for sensing a position on the rail 21 of the auxiliary drying unit 20 and includes a temperature sensor 32). 5, the sensing unit 30 senses the movement of the operation unit, senses the temperature of the warehouse 1, and outputs the sensed temperature to the control unit 40 in real time.

The position sensor 31 detects the position of the operating unit and restricts it from interfering with the warehouse 1 or the material 5. [ The position sensor 31 is configured as a switch type or a magnetic type interlocking with the operation unit and mounted on the rail 21 at a predetermined interval. Here, the actual position of the operation unit is detected by the drive wheel 24 or an encoder mounted on the feed motor 25, and the position sensor 31 serves to correct based on the encoder signal.

One or more temperature sensors 32 are mounted on the operation unit to sense the air temperature in the warehouse 1 and control the heat dissipation unit 11b or the heater 29a. The temperature sensor 32 is mounted on a rectangular frame of the frame 23. It is preferable that a plurality of temperature sensors 32 are installed in the height direction so that temperature can be distinguished from the upper, middle, and lower layers by convection. Here, the material 5 may further include a humidity sensor for sensing humidity according to characteristics, a smoke sensor for detecting a fire, and a gas sensor for sensing various gases.

At this time, the sensing unit 30 according to the present invention further includes a camera 35 for measuring the surface temperature of the material 5 on the operation unit and photographing the appearance of the material 5 in real time. The camera 35 measures the temperature of the material 5 as shown in Fig. 5, photographs the shape of the material, and outputs it to the control unit 40 in real time. It is preferable that the camera 35 is mounted on the pivotal table 26 so as to be able to take photographs in multiple directions, and a large number of cameras 35 are mounted in the height direction corresponding to the height of the material 5. [

The sensing unit 30 senses the temperature and the external shape of the air and the material 5 in the warehouse 1, thereby improving the drying and preventing various accidents.

The control unit 40 according to the present invention is connected in circuit with the central drying unit 10, the auxiliary drying unit 20, and the sensing unit 30, and performs feedback control of the operation according to the set values. 1, the control unit 40 includes a controller 41 for outputting a signal for controlling the central drying unit 10 and the auxiliary drying unit 20 by comparing and determining the set values according to a signal sensed by the sensing unit 30, . That is, the controller 41 receives the air temperature and the temperature of the material 5 from the sensing unit 30 and controls the operations of the central drying unit 10 and the auxiliary drying unit 20 in a feedback manner.

At this time, the control unit 40 according to the present invention further includes a terminal 45 connected to the server by wire or wirelessly, and transmitting the setting value while outputting information. The terminal 45 provides a manager or an operator to monitor and operate the mobile phone 47 on / off line using a desktop 47 or a mobile 47 such as a notebook PC 46, a PDA or a smart phone, as shown in FIG. That is, the terminal 45 permits a plurality of administrators or workers to confirm the information in real time while giving a setting enabling the controller 41 to be set.

The terminal 45 converts the information transmitted from the controller 41 into graphics, documents, and bar codes, and converts the information into D / B so that the consumer or the buyer can inquire the drying history of the material 5 by wire or wireless. That is, the terminal 45 provides an environment for the administrator or the operator to set the controller 41 through the PC 46 or the mobile 47, and provides the consumer and the purchaser with the drying history of the material 5 To be provided as a graphic (chart), a document, and a bar code.

In this way, real-time monitoring and control is supported remotely from outside, automatic trouble and accident occurrence can be determined, and emergency recovery and situation coping can be promptly taken, thus improving overall drying and preventing accidents. Since the history can be inquired from wired or wireless, the material (5) can be uniformly dried with high reliability and excellent quality.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

1: Warehouse 5: Material
10: central drying section 11: supply duct
11a, 15a, 27: a blowing fan 11b: a heat-
15: exhaust duct 20: auxiliary drying section
21: rail 23: frame
24: drive wheel 25: feed motor
26: Rotating base 28: Rotating motor
29: Protection net 29a: Heater
30: sensing part 31: position sensor
32: temperature sensor 35: camera
40: control unit 41:
45: Terminal 46: PC
47: Mobile

Claims (8)

CLAIMS What is claimed is: 1. A system for drying large quantities of material in a warehouse, comprising:
A central drying unit having a supply duct for blowing / circulating the air heated by the heat source to the inside of the warehouse, and a discharge duct for discharging the air,
A rail connected to the storage in a predetermined direction and an operation unit moving in a direction in which the rail is engaged with the rail, the operation unit includes a drive wheel rotating in engagement with the rail, A rotary motor for driving the rotary motor, a rotary motor for rotating the rotary motor, a rotary motor for rotating the rotary motor, a rotary motor for rotating the rotary motor, An auxiliary drying unit having an auxiliary drying unit;
A sensing unit having a position sensor for sensing a position on a rail of the auxiliary drying unit and a temperature sensor for sensing a room temperature on the operation unit; And
And a controller connected to the central drying unit, the auxiliary drying unit, and the sensing unit in a circuit to feedback-control the operation according to the set value. The method according to claim 1,
Wherein the heat source of the central drying unit is either one of a fossil energy using electricity, gas, petroleum, or a natural energy collected by a solar heat absorbing plate, or uses two or more of them in parallel. The method according to claim 1,
Wherein the rails of the auxiliary drying unit are provided with one of a straight line, a cross line, and a waveform depending on a material partitioned in the warehouse. The method according to claim 1,
Wherein the operating unit further comprises a protection net for protecting the material from the blowing fan and blocking the inflow of foreign matter to the outer periphery of the frame. 5. The method of claim 4,
Wherein the operation unit further comprises a heater for heating the air by receiving a heat source in the protection net. The method according to claim 1,
Wherein the sensing unit further comprises a camera for measuring the surface temperature of the material on the operation unit and photographing the appearance of the material on a real time basis. The method according to claim 1,
The control unit may further include a terminal connected to the server by wire or wirelessly and transmitting a setting value while outputting information,
Wherein the terminal converts the information transmitted from the controller into a graphic, a document, and a barcode, and converts the information into a D / B so that a customer can inquire the drying history of the material on wire or wireless. delete

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