KR20150083309A - Multipurpose rotor assembly - Google Patents

Abstract

The purpose of the present invention is to provide a multipurpose rotor assembly. The present invention comprises: a rotor frame (10) having at least one or more inserting support units (12) in a radial direction based on a center portion; a shaft (14) which is installed in the center portion of the rotor frame (10) and supports the rotor frame (10) to be rotated by a rotary drive device; and an outer frame (16) having the rotor frame (10) therein. The shaft is rotationally connected to the outer frame (16) and is connected to the rotary drive device. The rotor frame (10) and the shaft (14) are embedded in the outer frame (16) to enable a modular rotary module (RM) to be vertically and horizontally installed in a three-dimensional manner.

Description

[0001] Multipurpose rotor assembly [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-purpose rotor assembly, and more particularly, to a multi-purpose rotor assembly which includes various devices such as a device for creating conditions necessary for machining an object to be processed such as food, The present invention relates to a new concept of a multi-purpose rotor assembly which can be universally used in apparatuses, and which can uniformly distribute temperature to objects to be processed in such various apparatuses, thereby maximizing processing efficiency and advantageous in mass production .

Generally, dried and shipped products such as red pepper, mushroom, jujube, radish, amber, dried persimmon, squid, steak, citrus, etc. (hereinafter referred to as dried objects for convenience) are often required to be dried and shipped . At this time, a wide space is required for a method of drying various objects to be dried on outdoor floors such as a roadside or an open space, and a natural drying method by solar heat and natural wind, and it is necessary to unfold a dried object after raining or after sunshine, Therefore, various agricultural and mariculture products to be dried are spread on the tray, and then the tray is stacked in a dryer in a multi-layered structure. The hot air is circulated in the multi-layered state of the drying tray to dry the various agricultural and horticultural products Devices are widely used. That is, the apparatus for drying agricultural and marine products has a structure in which the temperature of the circulating air is raised by using a heater after sucking the outside air, the drying object is dried by using the circulated air whose temperature is raised, In the drying apparatus of the agricultural and marine products, dry desks containing dried objects such as pepper are received in a stacked state in the vertical direction, and the drying operation is performed by circulating the heated air in the multi- .

However, in the case of conventional dry wipes, the dry air is only circulated around and is not continuously transmitted to the object to be dried

There is a problem that the object to be dried is corrupted during the drying process. Even if there is an air circulation hole in the dry teaspoon, the dry air is not properly supplied to each drying object, so that the drying object is rather corrupted in the process of storing the drying object by using the drying device in the drying device .

On the other hand, a heater device employing a heater is used to dry food such as red pepper. The electric heater employed in such a heater device irradiates radiant heat generated from a heater to a target object to be dried so as to be dried. In other words, in a drying apparatus using an electric heater, a drying operation is performed on a drying target object by directly irradiating the object with a radiant heat wave using the intrinsic wavelength generated in the heater.

However, there is a problem in that the conventional method of drying the foods such as red pepper and other various drying objects by hot air using the conventional heater is insufficient to uniformly distribute the dry warm air to the dried object, There is a problem that the self-structure of the apparatus is complicated and the mass production of the dried object is also insufficient.

On the other hand, conventionally, a heater using electric power as a heat source is mainly a nichrome wire made of nickel and chromium alloy as a heating element, and since the nichrome wire heater is constituted by an element of an electric circuit, time passes The oxidation reaction tends to cause a thinning phenomenon, and the physical properties of the heating body change due to the change in the resistance. As a result, the accuracy of the temperature control is lowered, the life is shortened, and the heating is partially cut off during use. Resulting in a fire accident.

Therefore, in recent years, ceramic heaters have been used in place of heaters such as general nichrome wire heating elements. Such ceramic heaters are widely used in places where heating is required, such as plastic houses, The use range is becoming wider.

In this case, the ceramic heater is often made of a heater capable of generating heat at a high temperature of 500 ° C or higher. The ceramic heater can be manufactured by preparing an alumina ceramic substrate by a ceramic tap casting method, A metallized ceramic sintered body structure in which an electric circuit is printed with a high melting point metal paste such as molybdenum and another ceramic substrate is stacked on the printed substrate in this manner and fired in a reducing atmosphere at a temperature of 1500 DEG C or higher As described above, by connecting a power source to an electric circuit formed in the co-fired ceramic sintered body, it becomes a high temperature heating element.

In the case of the ceramic heater, since tungsten and molybdenum paste are used as the heating metal for metalizing, in order to simultaneously burn these pastes on the ceramic substrate, it is often necessary to heat the ceramic paste to a high temperature of 1500 to 1600 ° C. If the uniform distribution of the dry heat source of the ceramic heater is not achieved, the manufacturing cost of the heater is increased and the manufacturing cost is increased.

Korean Patent Laid-Open No. 10-2012-0071689 (published on July 23, 2012) Korean Patent Publication No. 1998-065929 (published on October 15, 1998) Korean Patent Laid-Open Publication No. 1998-074898 (published on May 11, 1998)

SUMMARY OF THE INVENTION The present invention has been developed in order to solve the above problems, and an object of the present invention is to provide an apparatus for forming conditions necessary for processing an object to be processed such as food, a method for forming a condition necessary for drying an object to be processed such as a ceramic heater And it is possible to uniformly distribute the temperature of the object to be processed in a variety of devices, for example, when hot air is required or when cold air is required, thereby maximizing processing efficiency And is intended to provide a multi-purpose rotor assembly of a new structure which is remarkably remarkable in mass production of objects to be machined and installed on a large-capacity device or the like.

According to an aspect of the present invention, there is provided a rotor frame including at least one insertion supporting portion in a radial direction with respect to a center portion thereof. And a shaft provided at the central portion of the rotor frame to support the rotor frame to be rotated by the rotation driving device.

The motorcycle according to claim 1, further comprising an outer frame in which the rotor frame is embedded, wherein the shaft is connected to the rotation driving device so as to be rotatable relative to the outer frame, further comprising a door for opening / Wherein at least one of the rotor frame and the shaft is embedded in the outer frame.

The rotation drive device includes a drive motor; A drive sprocket provided on a motor shaft of the drive motor; A driven sprocket provided on the shaft, and a chain connected to the drive sprocket and the driven sprocket.

And a rotary module modularized with the rotor frame and the shaft installed in the outer frame is installed in the machining chamber three-dimensionally up, down, left and right.

The shaft is provided with a shaft housing on an outer circumferential surface thereof, and a heat insulating material is interposed between the shaft housing and an outer circumferential surface of the shaft, and the inner space portion of the shaft is connected to a cooling device to allow a cooling fluid to pass therethrough.

Wherein the inserting support portion of the rotor frame includes: a base support bar disposed at an outer circumferential surface of the shaft; A pair of rail bars connected to the base support bars at their proximal ends to form guide rails parallel to each other; And a pair of insert support bars connected to the leading end side of the rail bar and arranged in parallel with each other to form an insert guide hole therebetween, wherein a plurality of the insert supporting parts are arranged in the radial direction with respect to the center part And the shaft is inserted into the shaft coupling hole formed between the base support bars.

And a side panel disposed at both end portions of the inserting support portion.

Wherein the rotor frame and the shaft are housed in a machining chamber of an object to be mounted, and the machining chamber is provided with a slot for coupling with the insert guide hole on the distal end side of the insert supporting portion of the rotor frame, A stand is further provided in the processing chamber.

Preferably, the insert support bar has a cross section of a polygonal bar shape, the rail bar has a cross-sectional channel-like bar shape, and the base support bar has a bar shape having a square cross section.

Wherein the inserting support portion of the rotor frame includes: a base support bar disposed at an outer circumferential surface of the shaft; A pair of rail bars connected to the base support bars at their proximal ends to form guide rails parallel to each other; And a pair of insert support bars connected to the front end side of the rail bar and arranged in parallel to each other to form an insert guide hole therebetween, the pair of insert support bars being disposed at the front and rear positions of the respective inserting support parts May be further provided.

In the multi-use rotor assembly according to the present invention, since the drying object is uniformly rotated by the rotor frame while the object to be dried is put into each inserting support part of the rotor frame, the drying process, the aging process, Such as drying and aging, can be improved. Particularly, since the tray (table) and the machined article accommodated therein are rotated while being rotated by the rotation of the rotor frame, the hot air or the cold air is distributed in an even and uneven manner. Therefore, It is important to be able to create.

In addition, since the modularized rotor frame can be installed in the drying process chamber as much as necessary in the upper, lower, left, and right three-dimensional form, there is a problem that the drying efficiency is lowered due to the faithful function of distributing the dry warm air evenly to the object to be dried In order to distribute the warm air to the object to be dried, the structure of the apparatus is not complicated, and it is also advantageous in mass production of the object to be dried. When the modularized rotor frame is installed in a three-dimensional manner for mass production, it is possible to manage necessary articles (for example, food materials such as red pepper) with only one person. It is quite desirable in that the mass production is possible, and the mass production is possible, but the management is very easy.

In addition, in the present invention, the cooling fluid is allowed to pass through the inside of the shaft at the center of the rotor frame, thereby preventing the shaft from being deformed in a high temperature environment such as plastic working of the ceramic heater. The main difference is that the shaft has a structural strength that it can withstand in a high temperature environment.

1 is an exploded perspective view of a rotor frame and a shaft, which are a main part of a multi-purpose rotor assembly according to the present invention;
FIG. 2 is a perspective view showing a combined state of the rotor frame and the shaft,
3 and 4 are perspective views showing the structure of the rotary frame shown in FIG. 2 and the rotary module in which the shaft is incorporated in the outer frame.
FIG. 5 is a longitudinal sectional view showing the combined state of the rotor frame and the shaft shown in FIG. 1,
6 is a longitudinal sectional view showing the use state of the present invention
7 is a perspective view of a multi-use rotor assembly according to another embodiment of the present invention.
8 is a side view schematically showing the structure of another modified embodiment of the present invention

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

It is to be understood that the present invention may be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. The present invention should not be construed as limited to the embodiments described in Figs.

Referring to the drawings, a multi-purpose rotor assembly according to an embodiment of the present invention includes a shaft 14 coupled to a center portion of a rotor frame 10 having a plurality of inserting support portions 12, 12) is configured to be capable of supplying uniform hot air or cold air to the object while rotating the rotor frame (10) in a state in which a tray (4) (teabag) containing an object to be processed such as a food material is inserted and coupled . The present invention relates to a multi-purpose rotor assembly which is used for various purposes. For example, when machining an object to be processed such as drying, aging and fermentation at the time of processing food or food ingredients, uniform supply of hot air or cold air, There is a main feature in the functioning such as uniform supply of hot air during processing.

Each of the insert supporting parts 12 constituting the rotor frame 10 has a rectangular frame shape in which the base support bar 12A, the rail bar 12B and the insert support bar 12C are connected to each other.

That is, the base support bar 12A is a bar structure having a square cross section with a hollow inside. The rail bar 12B has a bar structure of a cross-sectional diagonal shape (cross-sectional channel shape). The insert support bar 12C has a cross-sectional straight plate structure.

Accordingly, the insert support part 12 of the rectangular frame structure in which the base support bar 12A, the two rail bars 12B and the two insert support bars 12C are connected to each other is constituted.

The base support bar 12A and the rail bar 12B of the insert support portion 12 are connected to each other by connecting means such as bolts, rivets or welding. That is, since the rail bar 12B has a bar-shaped structure with a cross-sectional channel shape, when the both ends of the base support bar 12A having the square bar structure with a cross section are inserted into the two rail bars 12B, the rail bar 12B and the base support bar (12A) may be connected by bolts or rivets or by welding. When the base support bar 12A and the two rail bars 12B are connected to each other, the openings formed on one side of the hollow portion of each rail bar 12B are arranged in the inner surface direction facing each other. Therefore, a pair of guide rails parallel to each other are formed by the inner space portions of the two adjacent rail bars 12B. In other words, the rail bar 12B is a bar structure having a cross-sectional channel shape with rail forming pieces at the upper and lower ends of the middle connecting rail piece. Since the one opening portions of the rail bars 12B are arranged in the inner surface direction facing each other, A pair of guide rails facing each other are formed by the rail bars 12B. The guide rails formed by the two rail bars 12B have a path through which the trays 4 (trays) do.

The rail bar 12B of the insert support part 12 and the two insert support bars 12C are also connected to one another by means of connecting means such as bolts, rivets or welding. That is, the rail bar 12B is a bar structure having a cross-sectional channel shape with the rail forming pieces at the upper and lower ends of the middle connecting rail piece. The insert support bar 12C has a cross- The two rail bars 12B and the two insert support bars 12C are fixed to each other by means of connecting means such as bolts, rivets, or welding with the insert support bars 12C, An insert guide hole is formed between two adjacent insert support bars 12C. The insert guide hole has a structure connected to a hollow portion (that is, a space portion forming the guide rail) inside the two rail bars 12B.

Therefore, the insert support portion 12 is formed in a rectangular box shape in which the base support bar 12A on the proximal end side, the two rail bars 12B on both sides and the two insert support bars 12C on the distal end side are mutually connected The front and rear surfaces of the insert support part 12 are communicated with each other so that the insert guide hole on the distal end side of the insert support part 12 and the guide rail groove on the inside of the insert support part 12 are mutually connected. In addition, a pinhole 11h is formed in the insert support part 12 to prevent the tray 4 from being detached in a state in which the tray 4 to be described later is inserted. A pin 11p is coupled to the pinhole 11h. The pinhole 11h and the fixing pin 11p serve as fixing means for preventing the tray 4 from being detached from the inserted state in the insertion supporting portion 12. This will be described later.

The rotor frame 10 has a windmill-type frame structure in which a plurality of inserting support parts 12 are arranged in a radial direction with respect to a center part. That is, the side panel 18 has a plate-like structure with a predetermined area. In the present invention, the side panel 18 has a rectangular plate structure. The side panel 18 has a plurality of The insert supporting portions 12 are arranged in the radial direction with respect to the central portion of the side panel 18 so that the plurality of inserting support portions 12 are arranged in the radial direction with respect to the central portion of the rotor frame 10 .

Specifically, the insert support portion 12 is formed in a rectangular frame shape in which the base support bar 12A, the rail bar 12B, and the insert support bar 12C are connected to each other. Both ends of the insert support bar 12C are connected by a connecting means such as a bracket and a bolt or nut, welding or the like and at the same time, each inserting support part 12 is inserted in the radial direction with respect to the center of the side panel 18 So that the rotor frame 10 has a windmill-type frame structure in which a plurality of inserting support parts 12 are arranged in the radial direction with respect to the central part. In the present invention, the rotor frame 10 is a windmill type frame structure having four insertion supporting portions 12 with respect to the center portion. Of course, the insertion support portion 12 may be four or more or four or less. The number of the insertion support parts 12 can be increased or decreased as needed.

Since the insert supporting part 12 is disposed in the radial direction with respect to the center of the rotor frame 10 and both end parts are supported by the two side panels 18 so that the proximal end side is adjacent to each other, A shaft coupling hole 10h is formed at the center of the rotor frame 10 by the base support bar 12A of the support part 12. [ At this time, since the base support bar 12A on the base end side of the insert support part 12 has a hollow bar structure with a square cross section, the shaft engagement hole 10h has a rectangular hole structure. The shaft engaging hole 10h at the center of the lot frame formed by the proximal end side of each inserting supporter 12 communicates with the shaft inserting hole 18h formed in the two side panels 18. The shaft insertion hole 18h of each side panel 18 is also in the form of a square hole and the sectional area is the same as the sectional area of the shaft coupling hole 10h of the rotor frame 10. [ As a result, the rotor frame 10 is provided with a plurality of inserting support parts 12 in the radial direction with respect to the central part, and one side panel 18 is provided at each end of the insertion supporting part 12 Shaped windshield frame structure.

A plurality of the insertion supporting portions 12 are radially arranged with respect to the central portion so that the shaft supporting holes 12a of the base supporting bars 12A constituting the respective inserting support portions 12 14 are inserted and joined.

In the present invention, the shaft 14 is provided with a shaft housing 14H on its outer circumferential surface. The shaft 14 has a circular cross-sectional structure with a space therein. The shaft housing 14H is provided on the outer circumferential surface of the shaft 14 by welding or the like. A heat insulating material 14I is interposed between the outer peripheral surface of the shaft 14 and the shaft housing 14H. The heat insulating material 14I is preferably a heat-resistant insulating material 14I that can withstand high temperatures. At this time, coupling holes are provided at both ends of the shaft housing 14H so that the outer circumferential surface of the shaft 14 and the coupling holes of the shaft housing 14H can be sealingly coupled by welding or the like. In the present invention, the shaft housing 14H is a square cross-sectional sleeve structure.

Therefore, the shaft 14 can be inserted into the shaft coupling hole 10h provided at the center of the rotor frame 10 and coupled. The shaft housing 14H on the outer circumferential surface of the shaft 14 has a rectangular cross-sectional sleeve structure and is rotatably supported by the base support bars 12A on the proximal end side of each inserting support portion 12 of the rotor frame 10, The shaft housing 14H is tightly fitted to the shaft coupling hole 10h of the rotor frame 10. Since the shaft coupling hole 10h formed in the center of the rotor frame 10 has a rectangular hole structure, The four sides of each shaft housing 14H on the outer circumferential surface of the shaft 14 are in contact with the surface of the base support bar 12A provided at the proximal end side of each inserting support portion 12 of the rotor frame 10, The rotor frame 10 has a structure that is coupled to the center of the rotor frame 10. Further, the shaft 14 is joined to the center of the rotor frame 10 by a known fixing means such as a bracket and a bolt or nut, welding, or the like. In the present invention, flange portions extending radially outward are formed at both ends of the outer circumferential surface of the shaft housing 14H, and flange portions are fastened to both side panels 18 constituting the rotor frame 10 by bolts, nuts, welding or the like So that the shaft 14 is stably inserted into and fixed to the central shaft coupling hole 10h of the rotor frame 10. And the shaft 14, the heat insulating material 14I and the shaft housing 14H are coupled to the central shaft coupling hole 10h of the rotor frame 10. [ The base support bar 12A of each inserting support portion 12 is disposed at an outer position of the shaft 14, the heat insulating material 14I and the shaft housing 14H. A plurality of space portions are disposed in the radial direction at the outer circumferential surface of the shaft 14. In this case,

Further, the present invention further includes an outer frame 16 in which the rotor frame 10 is embedded. At this time, the outer frame 16 has various structure of the enclosure structure. In the present invention, the outer frame 16 has an enclosure structure in which the upper and lower surfaces are opened and the flange portions are provided at the upper and lower ends, respectively. A shaft (14) coupled to the center of the rotor frame (10) is connected to the rotation driving device by being connected to the outer frame (16) in a relatively rotatable manner. That is, in the state where the rotor frame 10 is housed in the outer frame 16, the outer peripheral surfaces of both ends of the shaft 14 are relatively rotatable relative to both side wall portions of the outer frame 16 via relative rotation means such as a bearing Thereby forming a rotary module RM in which the rotor frame 10 and the shaft 14 are embedded in the outer frame 16. The rotary module RM has a structure in which the components such as the outer frame 16, the rotor frame 10 and the shaft 14 are unitized so that the drying process chamber 2 of the drying device, 2), the plastic working chamber 2 of the firing apparatus, and the like. That is, when the rotor frame 10 and the shaft 14 are built in the outer frame 16, the rotor frame 10 and the shaft 14 are housed in the processing chamber 2 of the object to be mounted. The rotary module RM having a built-in structure is embedded in the processing chamber 2 of the object to be mounted, that is, the drying furnace of the drying apparatus, the cleaning processing chamber 2 of the cleaning apparatus, the plastic processing chamber 2 of the firing apparatus, Can be installed. It should be understood that the object to be mounted refers to a device in which the present invention is embedded, such as the drying device, the cleaning device, and the predetermined device. The machining chamber 2 is provided with an inlet 2h for receiving the insert guide hole at the distal end of the insert supporting portion 12 of the rotor frame 10, (2) is further provided with a stand (2a). And a stand 2a is further provided on the outer wall surface of the processing chamber 2. At this time, the inlet 2h of the outer wall of the processing chamber 2 is configured to be opened and closed by a door provided separately on the outer wall of the processing chamber 2. [ The door of the processing chamber 2 may be a door that is upwardly pivotally opened or closed with respect to the hinge portion, or may be a slide opening and closing door. It is to be understood that there is provided a structure for opening and closing the inlet 2h of the processing chamber 2 by the door, in other words, the inlet 2h through which the tray 4 enters. Particularly, in the present invention, it is possible to install a large number of rotor frames 10 and shafts 14 in the machining chamber 2 such as the drying apparatus in a large quantity in three dimensions. When the rotor frame 10 and the shaft 14 are a single-piece rotary module RM embedded in the outer frame 16, such a rotary module RM can be embedded in the processing chamber 2 of the drying apparatus, You can do it. At this time, the processing chamber 2 of the drying apparatus can be referred to as the processing chamber 2 as the drying processing chamber 2. On the other hand, when the rotary module RM is mounted on the upper, lower, left, and right three-dimensionally, fasteners such as bolts coupled to the fastening holes of the flange of the outer frame 16 are coupled to a support (not shown) provided in the processing chamber 2 . When the rotary module RM is stacked up and down, the flanges provided on the upper and lower rotary modules RM are stacked and fixed, and fastened by fasteners such as bolts commonly coupled to the fastening holes of the flange, The rotary module RM may be stacked up and down. It is preferable to form the injection holes on at least both sides of the outer frame 16 in consideration of the fact that the rotary modules RM are installed in three dimensions.

A rotation driving device is connected to the shaft 14. In the present invention, the rotation drive apparatus includes a drive motor 22, a drive sprocket 24 provided on the motor shaft of the drive motor 22, a driven sprocket 26 and a drive sprocket 24 and the chain 28 connected to the driven sprocket 26. In this case, when the motor shaft of the drive motor 22 rotates, the rotary shaft and the rotor frame 10 are rotated relative to the outer frame 16 Therefore, the radial insertion support portion 12 of the rotor frame 10 rotates in a windmill-like manner. Since the outer frame 16 is fixed to the processing chamber 2 such as a drying apparatus by means of fixing means such as bolts or rivets, the radial direction insert support portion 12 of the rotor frame 10 is inserted into the processing chamber 2 ), It turns out to be windmill-type. The outer frame 16 may be omitted and the shaft 14 may be connected to the outer wall of the processing chamber 2 such as a drying apparatus via a relative connecting means such as a bearing. Rotation will cause the radial insert support portion 12 of the rotor frame 10 to rotate in a windmill-like manner with respect to the processing chamber 2. It is also possible to replace the drive sprocket 24, the driven sprocket 26 and the chain 28 constituting the rotary drive device with a drive pulley, a driven pulley and a belt, The shaft 14 may be driven by a driving force. All of the rotation driving means capable of rotating the rotor frame 10 and the shaft 14 together can be employed.

In the present invention, the main parts of the rotor frame 10 and the shaft 14 are embedded in the drying processing chamber 2 or the like of the drying apparatus. According to the present invention having such a configuration, processing (for example, , Aging, washing, etc.) will be described as follows. The present invention is used for various purposes such as drying, aging, and washing of food.

First, a tray 4 containing food ingredients is put into each of the inserting support parts 12 constituting the rotor frame 10. A tray 4 (i.e., a rectangular box-shaped trapeze) containing an object to be processed such as a food material for drying is inserted from an insert guide hole on the leading end side of the inserting support portion 12 to an inner guide rail groove of the inserting support portion 12 So that the tray 4 can be coupled to the insertion support part 12. [ In other words, from the insert guide holes formed between the two insert support bars 12C on the leading end side of the insert support part 12 to the guide rail grooves formed by the hollow parts inside the two rail bars 12B, The two rail bars 12B support both sides of the tray 4 and the two insert support bars 12C support the outer end of the tray 4 and the base support bar 12A, The tray 4 is received in the insertion support part 12 and is stored therein by supporting the inner end of the tray 4. [ More specifically, when the box-shaped tray 4 is received in the insertion support portion 12, the two rail bars 12B are moved forward and backward by the rail forming pieces and the connecting rail pieces, And the two insert support bars 12C support the front and rear surfaces on the outer end side of the tray 4 and the base support bar 12A abuts against the inner end of the tray 4 . As a result, the tray 4 is housed in the insert supporting portion 12. On the other hand, the tray 4 is supported by the fixing means in a state where the tray 4 is embedded in the insertion support portion 12. In the present invention, the fixing means is composed of the pinhole 11h and the fixing pin 11p of the inserting supporter 12. When the hole is formed in the tray 4, 11h and the tray 4 so that the tray 4 is received in the respective inserting support portions 12 of the rotor frame 10 so as not to come off the support pins 11h, do. At this time, the fixing pin 11p is provided with a threaded portion on a part of the outer circumferential surface, and the fixing pin 11p is coupled with the pinhole 11h of the insertion supporting portion 12 through the hole of the tray 4 in common A nut is coupled to the threaded portion of the fixing pin 11p so as to be pressed and fixed to the surface of the inserting support portion 12 to securely secure the tray 4 to the respective insertion support portions 12 of the rotor frame 10 . A boss having a hole at one side of the tray 4 is provided so that the pinhole 11h of the inserting support part 12 and the boss inner hole at one side of the tray 4, It is possible to maintain the state that the tray 4 is firmly received without being detached from the respective inserting support portions 12 of the rotor frame 10 by fixing the fixing pin 11p in common. On the other hand, the fixing pin 11p is fixed to only the pinhole 11h of the rotor frame 10 without the fixing pin 11p being inserted into the hole of the tray 4 so that the tray 4 is fixed to the fixing pin 11p So that it is prevented from being detached from the insertion support portion 12 of the rotor frame 10 when it is caught. That is, in the state where the tray 4 is inserted into each of the inserting support portions 12 of the rotor frame 10, the pinhole 11h formed in the inserting support portion 12 is fitted with the fixing pin 11p, (That is, a side surface portion opposite to the side surface portion that is in contact with the base support bar 12A out of the four side surface portions of the tray 4) is caught by the fixing pin 11p, It is also possible to prevent the tray 4 from being detached from the insertion support part 12. [

In the present invention, the rotor frame 10 and the shaft 14 are housed in the processing chamber 2 of the object to be mounted. When the rotor frame 10 and the shaft 14 are built in the outer frame 16 A rotary module RM having a single structure is installed in the processing chamber 2 of the object to be mounted, that is, in the drying furnace of the drying apparatus. The rotor frame 10 is intermittently rotated, The insert guide hole at the tip end side of the part 12 is brought into contact with the inlet port 2h of the processing chamber 2 and then a part of the tray 4 The insertion hole 2h of the processing chamber 2 and the insert guide hole of the insertion support portion 12 of the rotor frame 10 along the stand 2a are used to insert the tray 4 into the insert supporting portion (12). Then, the tray 4 containing the food to be dried is stored in each of the inserting support portions 12 arranged in the radial direction of the rotor frame 10.

Next, the shaft 14 and the rotor frame 10 are rotated by the rotation driving device connected to the shaft 14 at the center of the rotor frame 10, and the hot air supplied to the inside of the drying processing chamber 2 is supplied to the tray 4 ) To dry the ingredients inside. At this time, the tray 4 housed in each of the insert supporting portions 12 of the rotor frame 10 rotates while being uniformly rotated by the rotation of the rotor frame 10, so that hot air is distributed evenly to the object to be dried So that good quality drying can be achieved.

Therefore, in the multi-use rotor assembly according to the present invention, the object to be dried is put into each inserting support part 12 of the rotor frame 10, and the object to be dried is uniformly rotated by the rotor frame 10, Washing, and the like. Thus, there is an advantage that processing efficiency such as drying and aging of the object to be dried is improved.

For example, in the case of food drying, conventionally, the drying air is not properly supplied to each drying object. Therefore, the drying object is rather corrupted in the process of storing the drying object by using the drying agent in the drying device, However, since the present invention rotates the object to be dried like a windmill evenly and supplies the dry hot air evenly to the object to be dried, the drying efficiency of the object to be dried and the corruption phenomenon of the object to be dried are effectively blocked.

In addition, the conventional method of drying foods such as red peppers and other dried objects with hot air using a heater is insufficient to evenly distribute the dry warm air to the object to be dried, However, in the present invention, the rotor frame 10 having a modular structure is installed in the drying and processing chamber 2 at the upper and lower portions thereof Therefore, there is no problem that the drying efficiency is lowered due to the fulfillment of a faithful function for evenly distributing the dry warm air to the object to be dried. In order to distribute the warm air to the object to be dried, In the mass production of the dried object, Group has a workable advantages. If the modularized rotor frame 10 is installed in a cubic manner for mass production, a necessary article (e.g., a food material such as pepper) can be sufficiently managed by only one person. The rotor frame 10 can be mass-produced while easily and stably increasing or reducing the number of the rotor frames 10 as required, and it is quite preferable in that mass production is possible and management is very easy. Of course, the rotary module RM modularized in the above-mentioned single item type is inserted into the processing chamber 2 (here, the processing chamber 2 referred to in the present invention is referred to as the drying processing chamber 2 of the drying apparatus, (Which means a processing chamber 2 that can process an article requiring processing such as a predetermined processing chamber 2 of a ceramic heater and a predetermined processing chamber 2 of a ceramic heater firing apparatus) The shafts 14 of all the individual rotary modules RM can be rotated together by connecting the shafts 14 constituting the rotary shafts 14 to each other by the coupler so that one shaft 14 is rotated by the rotary drive device will be.

In addition, the present invention can be satisfactorily utilized in firing ceramic heaters. The ceramic heater is often made of a heater capable of generating heat at a high temperature of 500 ° C or more. To this end, a heating process at a temperature of 1500 ° C or more is required during the ceramic heater firing process. When the rotor frame 10 is rotated while the ceramic heater to be subjected to the plastic working is housed in the heating support part 12, the high-temperature drying wind is evenly distributed to the respective ceramic heaters to be processed. Thus, So that it is possible to prevent the manufacturing cost of the heater from being increased, thereby solving the problem of increasing the manufacturing cost. In particular, since the drying process is performed while supplying the evenly dried hot air while rotating the ceramic heater, the quality of the ceramic heater is further enhanced.

Further, in the present invention, the cooling fluid is allowed to pass through the shaft 14 at the center of the rotor frame 10, thereby preventing the shaft 14 from being deformed in a high temperature environment such as plastic working of the ceramic heater. In the present invention, a cooling device is connected to the shaft 14 at the central portion of the rotor frame 10 via a connection pipe, and the cooling device is constituted by a known cooling cycle, so that the refrigerant The shaft 14 of the rotor frame 10 is prevented from being deformed due to high temperature. At this time, the coupling pipe connecting the shaft 14 and the cooling device is relatively rotatably coupled to the shaft 14 so that the coupling pipe is fixed in place when the shaft 14 is rotated. In this way, there is no possibility that the connecting tube will rotate together with the shaft 14. The shaft 14 is provided with a shaft housing 14H on the outer circumferential surface thereof and the heat insulating material 14I is interposed between the shaft housing 14H and the outer peripheral surface of the shaft 14, It is possible to prevent excessive heat from being transmitted to the shaft 14 by the heat insulating member 14I and to prevent the cooling fluid passing through the shaft 14 from being heated when the heat insulating member 14I blocks the heat, 14I also contribute to prevention of deformation (deterioration due to high temperature) of the shaft 14. [

Further, in the present invention, the base support bar 12A on the base end side of each of the inserting support parts 12 constituting the rotor frame 10 has a hollow cross-sectional square pipe structure with a space inside, Since the hollow space portion is secured to the outer peripheral surface of the shaft 14 by the base support bars 12A by the respective base support bars 12A and 12B, Since the rotor frame 10 itself is a hollow pipe, the overall weight is also reduced, which is more effective in reducing the load during installation and operation. Particularly, the rail bar 12B, which is another constitution of the insert support part 12, is also a channel-type bar structure having a hollow space therein, and the insert support bar 12C is also a plate- Which is more advantageous in reducing the load during installation and operation.

In the present invention, the side panels 18 are further provided on both side surface positions of the rotor frame 10 so as to prevent the inserting support part 12 from being warped due to the high temperature of the side panels 18. It works effectively. In the present invention, the main components of the rotor frame 10, the shaft 14, and the side panel 18 may be made of a metal material, or may be made of a ceramic material as the case may be. Since the side panels 18 are further provided on both side surfaces of the rotor frame 10, the insert supporting portions 12 of the rotor frame 10, which is the main part of the rotor frame 10, are twisted and deformed under high- Thereby more reliably preventing it. Preferably, the side panel 18 is formed in a plate shape having a certain thickness (approximately 30 mm or more), so that the insert supporting portion 12 (specifically, the rail bar 12B, the insert guide plate, etc.) The deformation phenomenon can be almost completely prevented. Since the side panel 18 is made of a relatively thick plate structure of 30 mm or more rather than being made of a thin plate, the main part of the rotor frame 10 due to the high temperature can be prevented from being twisted.

In the present invention, the outer frame 16 of the rotary module RM is provided with an inlet and an outlet at least on both sides facing the insert guide hole on the distal end side of the insert supporting portion 12 of the rotor frame 10, The door 16D is provided on the outer frame 16 and the door 16D is provided on the outer frame 16 so that the outer frame 16 And may be configured to open and close the entry / exit hole 16h. In this case, the outer frame 16 of the rotary module RM itself functions as the processing chamber 2. That is, the outer frame 16 of the motor module RM itself functions as the processing chamber 2 when connecting the rotary module RM in the front, rear, left, and right up and down. The upper and lower outer frames 16 function as the processing chambers 2 when the plurality of rotary modules RM are mounted on the upper and lower sides. When the rotary modules RM are connected in the front, rear, left and right directions, So that the frame 16 functions as the processing chamber 2. As described above, when the rotary module (RM) is installed vertically, horizontally, vertically, and laterally in a three-dimensional form, the productivity of the object to be processed is significantly increased. At this time, when the drive motor 22 is mounted on the outer frame 16, the rotary drive means such as the drive motor 22, the drive sprocket 24, the driven sprocket 16, Integrated configuration can be taken.

The door 16D may be configured such that the upper end of the door 16D is vertically opened and closed with respect to the hinge portion by being attached to the outer frame 16 via a hinge portion When the hole 16h is closed, the closed state of the door 16D can be firmly held by the locking device (such as a clamp). See FIG.

When the door 16D is provided on the outer frame 16, the door 16D is opened to allow the tray 4 to be inserted into the respective inserting support portions of the rotor frame 10 Hole 16h of the outer frame 16 is closed by the door 16D and the tray 4 (or the object to be processed) containing the object to be processed can be checked by inserting the tray 4 Can be performed. The door 16D is firmly closed by the locking means so that the door 16D of the outer frame 16 is not opened during processing of the object.

At this time, instead of the door 16D, a transparent tempered glass is provided on the outer frame 16 to open and close the entrance and exit holes 16h of the outer frame 16 by the tempered glass, The processing state of the object to be processed can be confirmed through the tempered glass.

8, at least two rotor frames 10 and a shaft 14 are provided in an outer frame 16 of the present invention. A shaft 14 of each of the rotor frames 10 is provided with a drive motor 22, a drive sprocket 24, a driven sprocket 26, and a chain 28 are connected to each other. The drive motor 22 and the drive sprocket 24 and the rotary drive means such as the driven sprocket 16 and the chain 28 are mounted on the outer frame 16 in the embodiment shown in Fig. It is possible to adopt a configuration in which it is incorporated in the rotary module RM.

8, in the case of the rotary module RM in which the two rotor frames 10 are built in the outer frame 16, if the rotor frames 10 are rotated in opposite directions to each other, (More precisely, the inside of the outer frame 16), so that the utilization of the object to be machined becomes higher. When two rotor frames 10 are rotated in opposite directions, two rotor frames 10 can be rotated in the same direction or in opposite directions, So that it can be circulated to the inside of the rotor frame 10. As shown in FIG. 8, it should be understood that, in the present invention, a plurality of rotor frames 10 and a shaft 14 may be built in the outer frame 16 constituting the rotary module RM, It should also be understood that the rotor frame 10 and the shaft 14 can be added and subtracted as required.

7 is a perspective view showing a main structure of another embodiment of the present invention. In another embodiment of the present invention shown in Fig. 7, at least the insert support bar 12C of the main part of the inserting support part 12 has a cross-section of a polygonal bar shape. In the present invention, the insert support bar 12C is in the shape of a triangular cross section bar. At this time, the base support bar 12A and the rail bar 12B, which are other parts of the insert support part 12, may also have a polygonal cross section.

Therefore, in the case of the embodiment shown in Fig. 7, the force against the warping stress caused by the heat is stronger, so that it is more advantageous to prevent the distortion of the rotor frame 10 itself.

Meanwhile, FIG. 7 is a perspective view showing a main configuration of another embodiment of the present invention. The present invention as shown in FIG. 7 is further provided with a pair of multi-faceted nets arranged so as to be disposed at the front and rear positions of the respective inserting support portions 12 of the rotor frame 10. The network can be a mesh network. In the case of FIG. 7, since the tray 4 (trays) inserted into the insertion support portion 12 is supported by both sides of the front and back surfaces, the post-insertion stability of the tray 4 is further enhanced. Of course, even distribution of high-temperature hot air or cool air to the tray 4 will not be disturbed by the cellular network.

It is to be understood that the terms "comprises", "comprising", or "having" as used in the foregoing description mean that a component can be implanted unless specifically stated to the contrary, But should be construed as further including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

2. Processing chamber 2a. stand
2h. Inlet 4. Tray
10. Rotor frame 10h. Shaft coupling hole
11h. Pinhole 11p. Fixing pin
12. Insert support part 12A. Base support bar
12B. Rail bar 12C. Insert support bar
14. Shaft 14H. Shaft housing
14I. Insulation 16. Outer Frame
18. Side panel 22. Drive motor
24. Drive sprocket 26. Follower sprocket
28. Chain

Claims (10)

A rotor frame (10) provided with at least one insertion supporting part (12) in a radial direction with respect to a central part;
And a shaft (14) provided at the central portion of the rotor frame (10) to support the rotor frame (10) to be rotated by a rotation driving device.
The method according to claim 1,
The motorcycle according to claim 1, further comprising an outer frame (16) in which the rotor frame (10) is embedded, the shaft (14) being connected to the rotation drive device so as to be rotatable relative to the outer frame And a door (16D) for opening and closing the input / output hole (16h) is further provided in the outer frame (16). At least one or more of the rotor frame (10) and the shaft (14) Rotor assembly.
3. The method of claim 2,
Wherein a rotary module (RM) having the rotor frame (10) and the shaft (14) built in the outer frame (16) is installed vertically and horizontally.
The method according to claim 1,
The shaft 14 is provided with a shaft housing 14H on the outer circumferential surface thereof and a heat insulating material 14I is interposed between the shaft housing 14H and the outer peripheral surface of the shaft 14. The inner space portion of the shaft 14 Is connected to a cooling device to allow cooling fluid to pass therethrough.
The method according to claim 1,
The inserting support portion (12) of the rotor frame (10)
A base support bar 12A disposed at an outer circumferential surface of the shaft 14;
A pair of rail bars 12B connected to the base support bars 12A at their proximal ends to form guide rails parallel to each other;
And a pair of insert support bars 12C connected to the front end side of the rail bar 12B and arranged side by side to form an insert guide hole therebetween,
A plurality of insertion supporting portions 12 are arranged radially with respect to a central portion thereof and the shaft 14 is inserted into a shaft coupling hole 10h formed between the base support bars 12A Wherein the rotor assembly comprises:
6. The method of claim 5,
Further comprising a side panel (18) disposed at both end portions of the insert support portion (12).
6. The method of claim 5,
Wherein the rotor frame 10 and the shaft 14 are embedded in a processing chamber 2 of an object to be mounted and the processing chamber 2 is provided with a front end portion 12a of the insertion support portion 12 of the rotor frame 10, Wherein a stand 2a is further provided in the machining chamber 2 so as to be provided at a lower portion of the loading port 2h.
6. The method of claim 5,
The insert support bar 12C has a cross section of a polygonal bar shape. The rail bar 12B has a cross-sectional channel-like bar shape. The base support bar 12A has a bar shape having a square cross section A rotor assembly.
6. The method of claim 5,
Characterized in that the tray (4) inserted into the inserting support part (12) of the rotor frame (10) is supported by means of fastening means.
The method according to claim 1,
The inserting support portion (12) of the rotor frame (10)
A base support bar 12A disposed at an outer circumferential surface of the shaft 14;
A pair of rail bars 12B connected to the base support bars 12A at their proximal ends to form guide rails parallel to each other;
And a pair of insert support bars 12C connected to the front end side of the rail bar 12B and arranged side by side to form an insert guide hole therebetween,
Further comprising a pair of porous substrates disposed at front and back positions of the respective inserting support parts (12).

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