KR101511510B1 - Spiral stairway type spread dryer with hitting apparatus - Google Patents

Abstract

The present invention relates to a spiral stepped scattering dryer having a striking device.
A spiral stepwise scatterer dryer having a striking device of the present invention includes an inner case having a rotating shaft vertically installed at an inner center thereof; A spiral blade provided in a spiral shape along the inner circumferential surface of the inner case in a state of being separated from the inner circumferential surface of the inner case and connected to the rotary shaft by a stirring blade; A flare blade protruding upwardly from an upper surface of the spiral blade and guiding scattering of the object to be dried rising along the spiral blade; And a heating medium case provided on an outer side of the inner case and having a spiral heating medium passage formed therein. One side of the heating case is connected to each of the stirring blades, and the other side of the heating case can freely rotate from one connection point A weight member provided on the other end of the elongated member and adapted to strike an inner wall surface of the inner case with weight according to the rotation of the stirring vane, And a striking device having a rotation radius of the stirring blade shorter than the distance between the upper and lower stirring blades.
According to the present invention, the scaling is stably performed by striking the inner wall of the case without striking the stirring wings adjacent to the scattering wings located inside the spiral step-wise scattering dryer, thereby maximizing the continuous heat transfer efficiency.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a spiral stairway type spreading dryer with a hitting apparatus,

The present invention relates to a dryer, in which a spiral blade that spirally rotates inside a cylinder is provided, a scattering blade for scattering the laundry to be dried is provided, and a heating medium passage is formed spirally outside the cylinder to maximize drying efficiency , And a spiral stepped scattering dryer equipped with a striking device.

BACKGROUND OF THE INVENTION [0002] Drying processes have been widely used in various industrial fields to remove moisture from a liquid, fluidized bed, semi-liquid phase, powdery or granular bedded material such as food wastes, and drying and recycling.

Among these technologies related to various types of dryers, "drying device" (Korean Patent Laid-Open Publication No. 10-1993-0008423, Patent Document 1) has been disclosed with a technique using spiral wings.

In addition, a spiral impeller was installed in a "vertical vacuum heat-drying dryer" (Korean Utility Model Laid-Open Utility Model No. 20-0166270, Patent Document 2) so that drying was carried out while the laundry was moved in a spiral manner.

In the above-described technologies of Patent Documents 1 and 2, wings are attached in a spiral shape to a rotary shaft disposed vertically in a container, and a heat transfer surface is provided on an inner wall surface of the container. Thus, So that the drying efficiency can be improved by thinning the inner wall surface and the thin film as the heat transfer surface.

However, in the case of organic wastes having a high water content, even though the above-mentioned helical wings are used, there is a problem that the drying efficiency is decreased because the water content is so high that the weight of the wastes increases along the helical wings while being spread thinly on the inner wall surface.

In order to solve this problem, when a heat source of high temperature is used, there is a problem that a fire occurs due to unevenness of the drying state.

In order to solve such a problem, the inventor of the present application invented the "spiral stepped scattering dryer" (Korean Patent Registration No. 10-1285342, Patent Document 3).

In Patent Document 3, a spiral blade that rotates spirally along the inner circumferential surface of the inner case is provided on the rotary shaft, and a heat medium case through which the heat medium flows into the outer side of the inner case is provided. Inside the heat medium case, So that the object to be dried spreads thinly over the spiral wing and is lifted up and scattered and closely adhered to the inner wall surface of the inner case, and the scattered dried object is heated in a short time and the moisture is evaporated in the scattering state, .

However, in the process of being spread while being thinly spread on the wall surface of the container, organic wastes are often pressed on the wall surface of the high-temperature heating medium case.

This phenomenon is known as a "sludge dryer" (Korean Patent Registration No. 10-0416988, Patent Document 4), in which a scraper is installed inside a screw-type dryer to scrape dry matter sticking to a wall surface.

However, the scraper scraped by the scraper must have a copper line corresponding to the entire area of the inside wall of the case.

That is, when a portion of the scraper tip portion that does not touch the partially pressed portion of the dried material occurs, the dried material pressed on the portion is continuously accumulated, resulting in a decrease in drying efficiency and a malfunction.

Particularly, as in Patent Document 3, which is not a simple screw type, the air flow of the internal space must be performed as originally planned, and when the vortex is partially generated, the drying efficiency is further lowered.

Further, when the spiral blade rises while rotating upwardly in the inner wall surface of the case, there is a problem that the scattering wing formed on the upper part of the helical wing is caught by the protruding part, .

Therefore, it is necessary to develop a technique capable of desorbing the dried material pressed against the wall, which is suitable for the non-acid drying method as in Patent Document 3, instead of the general screw drying method.

KR 10-1993-0008423 (May 22, 1993) KR 20-0166270 (October 26, 1999) KR 10-1285342 (2013.07.05) KR 10-0416988 (Jan. 17, 2004)

The spiral stepped scatterer dryer having the striking device of the present invention is provided to solve the problems caused by the conventional art as described above. The spiral staircase scatterer dryer includes a stirring member having a length member such as a chain or a wire, The centrifugal force generated by the rotation of the agitating blades strikes the inner wall surface of the weight-added case to remove the scale sticking to the inner wall surface, thereby maximizing the continuous heat transfer efficiency.

Particularly, the turning radius of the weight weight provided on the surface of the helical wing is made shorter than the distance between the upper and lower stirring wings so that damage to the adjacent stirring wing due to the rotating copper wire is prevented.

In addition, the striking device is configured to be movable to the center and the outer side on the stirring vane by the sliding member, so that the striking force can be controlled by adjusting the distance.

In addition, the ends of the stirring vanes are formed so as to be inclined upward or downward so that the rotating copper wire of the weight weight is prevented from being disturbed by the stirring vane when the centrifugal force is directed toward the horizontal additional direction with the weight addition stirring vane.

In addition, by forming the impact preventing jaw on the inner circumferential surface of the helical wing connected to the stirring wing, it is intended to prevent the flying wing provided on the helical wing from being hit by the weight.

In order to solve the above-described problems, a spiral stepwise scattering dryer having a striking device according to the present invention is formed with an inner hollow cylinder, a rotary shaft 11 vertically installed therein, An inner case 10 having a driving motor 12 connected to the rotating shaft 11 and capable of adjusting a speed and a rotating direction of the rotating shaft 11; One side of which is connected to the rotating shaft 11 and the other side is installed horizontally toward the inner wall surface of the inner case 10 and spaced apart from the inner wall surface, A plurality of agitating blades (20) arranged on the side surface and having a plurality of vertically spaced apart layers; One side and the other side of which are connected to a stirring blade 20 which forms upper and lower adjacent layers and is formed in a spiral shape inclined up and down and is provided along the outer side of the stirring blade 20, A spiral wing 30 on which the spiral blade 30 is installed; The spiral blade 30 has a round portion 41 which is upwardly protruded from the upper surface of the spiral blade 30 and has a spiral shape toward the rotary shaft 11 on a plane and is formed on one side in an upward direction And a resistance accommodating portion 42 is formed on the opposite side of the round portion 41. The rotary pin 43 is inserted between the round portion 41 and the resistance accommodating portion 42 The rotation pin insertion hole 44 is curved in the same direction as the round portion 41 with a width larger than the diameter of the rotation pin 43, The wing 40 is configured so as to be able to move forward or backward with respect to the rotary pin 43. The rotary section 43 can be moved up or down as the rotary section 43 rotates about the rotary pin 43 (Not shown) of the laundry A scattering wing (40) for guiding scattering; A spiral staircase member 50 which is provided in a spiral shape along the outer circumferential surface of the inner case 10 so as to be in contact with the outer circumferential surface of the inner case 10 and forms a heating medium passage 51 between upper and lower adjacent layers, ; The heating medium inlet pipe 61 and the heating medium discharge pipe 62 are connected to one side and the other side respectively and the inner wall faces the other side of the helical step portion, (60); A heat insulating material 70 surrounding the outer peripheral surface of the heating medium case 60; A heat insulating case (80) enclosing an outer circumferential surface of the heat insulating material (70); A length member 94 connected at one end to the stirring vanes 20 and freely rotatable from one connection point at the other side and a weight member 91 disposed at the other end of the length member 94, And the weight weight 91 strikes the inner wall surface of the inner case 10 in accordance with the rotation of the stirring vane 20, And a striking device (90) whose turning radius is shorter than the distance between the upper and lower stirring blades (20).

At this time, the length member 94 is formed with a sliding hole 92a into which the stirring vane 20 is inserted, and is connected to a sliding member 92 which moves along the stirring vane 20, A bolt fastening hole 92b is formed on one side of the member 92 and a fixing bolt 93 screwed to the bolt fastening hole 92b and having a lower end for pressing and fixing the stirring vane 20 is provided .

In addition, the stirring vane 20 is characterized in that an inclined portion 21 is formed on the end portion thereof so as to be inclined upward or downward.

In addition, the helical blade (30) is characterized in that a blow-off prevention tuck (31) protruding upward is formed on the inner circumferential surface.

In addition, the weight 91 is made of soft material and is replaceable from the length member 94.

According to the present invention, a weight member such as a chain, a wire, or the like is provided on a stirring blade, a weight weight is provided at an end thereof, and a centrifugal force generated by the rotation of the stirring vane strikes the inner wall surface of the weight- Thereby maximizing the continuous heat transfer efficiency.

Particularly, the turning radius of the weight weight provided on the surface of the spiral wing is made shorter than the distance between the upper and lower stirring wings so that damage to the adjacent stirring wing by the rotating copper wire of the weight weight is prevented.

In addition, the striking device can be moved to the center and the outer side on the stirring vane by the sliding member, so that the striking force can be adjusted by adjusting the distance.

Further, when the end portion of the stirring blade is formed to be inclined upward or downward, the rotation copper wire of the weight weight is prevented from being disturbed by the stirring blade when the centrifugal force is directed to the horizontal additional direction with the weight addition stirring blade.

Further, by forming the impact preventing jaw on the inner circumferential surface of the helical wing connected to the stirring wing, it is possible to prevent the flying wing provided on the helical wing from being hit by the weight.

As a result, the scale can be stably removed by striking the inner wall of the case without striking the stirring blade adjacent to the scattering wings located inside the spiral stepped scattering dryer, thereby maximizing the continuous heat transfer efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional schematic view showing one embodiment of a spiral stepwise scatterer dryer having a striking device of the present invention. FIG.
2 is a partially cut exploded perspective view showing a spiral stepped scattering dryer having a striking device of the present invention.
3 is a partial cutaway perspective view showing a spiral stepped scatterer dryer having a striking device of the present invention.
4 is a cross-sectional schematic view showing still another embodiment of a spiral stepped scattering dryer having a striking device of the present invention.
5 is a side view showing one embodiment of a scattering wing in the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a spiral stepped scattering dryer having a striking device of the present invention will be described in detail with reference to the accompanying drawings.

As shown in the figure, the inner case 10, which is a component of the present invention, is formed in a hollow cylindrical shape and has a rotation shaft 11 vertically installed therein. The rotation shaft 11 is connected to the rotation shaft 11 And a driving motor 12 for rotating the driving motor 12 is disposed outside the upper portion.

At this time, a supply pipe 13 and a discharge pipe 14 may be installed on one side of the inner case 10 so that food items such as food wastes and organic wastes can be introduced into or discharged from the inner case 10.

The supply pipe 13 may be installed at the upper portion and the discharge pipe 14 may be installed at the lower portion of the supply pipe 13, And the discharge pipe 14 are provided on the side wall surface.

As shown in FIGS. 2 and 3, the stirring vane 20, which is a component of the present invention, has one side connected to the rotating shaft 11 and the other side disposed in a horizontal direction toward the inner wall surface of the inner case 10, And the other end is spaced apart from the inner wall surface of the inner case 10.

A plurality of such stirring vanes 20 are provided on the plane of the rotary shaft 11 as a center, and a plurality of stirring vanes 20 are vertically spaced from each other on the side surface.

In the drawing, four stirring vanes 20 are installed on one layer. However, the present invention is not limited to this, and may include two or three stirring vanes 20.

The spiral blade 30, which is a component of the present invention, has a spiral shape that is vertically inclined by being connected to a stirring blade 20, one side and the other side of which are vertically adjacent layers, As shown in Fig.

As shown in FIG. 5, the spiral blade 30 is provided with a rotation pin 43 on the upper surface thereof.

As shown in the drawing, the scattering vane 40, which is a constituent element of the present invention, is installed so that the spiral vanes 30 protrude upwards at regular intervals on the upper surface thereof to guide scattering of the objects to be dried rising along the spiral vanes 30 .

The scattering vanes 40 may be formed in a simple stick shape as shown in FIGS. 1 to 4, and more preferably, the scattering vanes 40 are curved in a spiral shape toward the rotating shaft 11 when viewed in a plan view.

When the scattering vane 40 is formed in the simple stick shape in the above-described configuration, when the weight of the object to be dried is high due to a high moisture content of the material to be dried or the scattering wing 40 is present in this layer, It can fall.

That is, the object to be dried overflows over the scattering vane 40 and may not scatter while passing through the scattering vane 40. In this case, the drying rate is inevitably lowered.

As a method for solving such a problem, the scattering vane 40 can be configured to be able to rotate while being slid upward as shown in Fig.

More specifically, the upper surface of the helical blade 30 is provided with a rotation pin 43 parallel to the upper surface when viewed from the side. For this purpose, a bracket for installing the rotation pin 43 is provided on the upper surface of the helical blade 30 .

In addition, the scattering vane 40 is provided with a round portion 41 formed on one side, that is, on the front side where the laundry is moved upwardly, A rotary pin insertion hole 44 into which the rotary pin 43 is inserted is formed on the side surface between the round portion 41 and the resistance accommodating portion 42, The rotation pin insertion hole 44 may be formed to be longer than the rotation pin 43 in diameter.

That is, the scattering vane 40 has a structure capable of rotating both sides of the rotation pin 43 as a seesaw as well as being movable to both sides while being fitted to the rotation pin 43.

The resistance receiving portion 42 formed on the rear side has a shape that is bent upward so that when the object to be dried moving on the spiral wing 30 pushes the resistance receiving portion 42, 44 are formed to have a long width, the scattering vane 40 can be moved while sliding on the front side.

At this time, the rotation pin insertion hole 44 is curved in the same direction as the round portion 41. When the resistance receiving portion 42 is pushed by the object to be dried, The round portion 41 is rotated upward along the true direction.

This is because the scattering vane 40 is configured to be able to move forward or backward with respect to the rotation pin 43. When the round portion 41 rotates about the rotation pin 43 as it advances or retreats, It is possible.

That is, as shown in the drawing, the upper end of the scattering vane 40 becomes higher according to the pressure of the object to be dried, and the object to be dried is forcibly raised and dropped to come into contact with air, The drying speed is shortened.

2 and 3, the helical step member 50, which is a component of the present invention, has a helical shape along the outer circumferential surface of the inner case 10 with one side thereof abutting the outer circumferential surface of the inner case 10 And the heating medium passage 51 is formed between upper and lower adjacent layers.

The helical stair member 50 may be configured to be continuously inclined to the same direction as the helical blade 30 to continuously supply heat to the drifting material moving along the helical blade 30 as shown in FIG. .

As shown in the drawing, the heating medium case 60, which is a component of the present invention, is connected to the heating medium inlet pipe 61 and the heating medium discharge pipe 62 through which the heating medium flows into and out from the one side and the other side, And it is installed while covering the stepped portion of the spiral while abutting against the other side of the portion.

The heating medium does not flow out to the outside of the inner case 10 or the heating medium case 60 and the inner case 10 is prevented from flowing through the heating medium passage 51 along the helical step member 50 And then discharged.

A plurality of known heat insulating materials 70 are wrapped around the outer circumferential surface of the heat medium case 60 so as to prevent heat of the heat medium inside the heat medium case 60 from being taken to the outside, and the heat insulating case 80, which surrounds the outer circumferential surface of the heat insulating material 70, Respectively.

The heating medium circulating along the heating medium passage 51 may be a variety of known heating mediums such as air, water, steam, and heating oil. The heating medium inlet pipe 61 and the heating medium discharge pipe 62 may heat the heating medium To a heating source such as a boiler.

At this time, the heating heat source is not limited to the boiler, but may be configured to supply waste heat. Alternatively, the heating source may be configured to connect the boiler and the waste heat to each other through a combined pipe to selectively receive the heat source through the boiler, something to do.

As shown in FIG. 1, the striking device 90, which is an important component of the present invention, includes a longitudinal member (not shown) having one side connected to each of the stirring vanes 20 and the other side capable of freely rotating from one connection point 94 and a weight 91 provided at the other end of the elongated member 94.

1, the weight weight 91 is rotated with respect to one end of the length member 94 fixed to the stirring vane 20 in accordance with the rotation of the stirring vane 20, The scale attached to the inner wall surface can be removed.

At this time, when the turning radius of the weight 91 is large, the stirring vanes 20 which are adjacent to each other may be struck or twisted with the respective length members 94 provided on the stirring vanes 20 adjacent to each other.

Therefore, the turning radius of the weight 91 is shorter than the distance between the upper and lower stirring vanes 20 on the basis of the point connected to the stirring vane 20.

The length member 94 for this purpose is shown as a chain in the figure, but is not limited thereto and may be composed of a wire, a string, a chain, or the like.

In addition, the weight 91 may be made of a hard metal or synthetic resin.

At this time, when the weight of the weight 91 is large, the striking energy is increased, which may cause damage to the inner wall.

In this case, the weight weight 91 itself may be made of a soft material such as rubber or a material coated with rubber or the like.

In addition, the length member 94, such as the illustrated chain, can be replaced using various known clamping devices to ensure continued maintenance.

4, another embodiment of the helical step member 50 is shown.

It can be seen that the system shown in the figure is arranged such that the inclined direction of the helical blade 30 and the inclined direction of the helical step member 50 are different from each other.

That is, when viewed from the side, they have a structure that intersects with each other.

This is because when the heating medium inlet pipe 61 is connected to the lower portion of the heating medium case 60, the heating medium rises spirally from the lower portion and the laundry drifts upward spirally from the bottom to the bottom. The heat medium is continuously heated along the heating medium passage 51 while being lifted to the drying object which rises together, so that the drying efficiency in the upper layer may be lowered.

In addition, the object to be dried, which reaches the uppermost end first and then drops again to the bottom of the inner case 10 and then moves along the lower spiral wing 30, is relatively low in moisture and has a high drying rate. A fire may be generated due to the high-temperature heating medium flowing from the lower heating medium inlet pipe 61.

On the other hand, if the helical wings 30 and the helical step members 50 are formed in a direction intersecting with each other, they are moved without being moved side by side so as to intersect with each other, so that the rate of heat- The heating medium is not continuously moved to the high temperature because the heating medium does not move along the stepped member 50 after falling down to the bottom of the inner case 10 after the drying process reaches the uppermost stage, Is reduced.

That is, it is possible to reduce the risk of fire by dryly drying the object to be dried as a whole.

In the above configuration, the change of the striking energy can be given through the adjustment of the turning radius of the weight 91.

Specifically, as shown in FIGS. 1 and 2, the length member 94 is formed with a sliding hole 92a into which the stirring vane 20 is inserted, so that the sliding member 92, which moves along the stirring vane 20, And a bolt fastening hole 92b is formed on one side of the sliding member 92. The lower end of the sliding member 92 is screwed to the bolt fastening hole 92b, A fixing bolt 93 is provided.

This configuration is configured such that the striking device 90 can be moved to the center and the outer side on the stirring vane 20 by the sliding member 92, so that the adjustment of the striking force according to the distance adjustment can be made.

The centrifugal force is generated when the stirring blade 20 rotates in the above configuration and the weighting device 90, particularly the weight 91 connected to the stirring vane 20, 20) in the horizontal direction.

One end of the elongated member 94 is connected to the agitating vane 20 so that a portion of the elongated member 94 may be caught by the agitating blade 20 to interfere with the movement of the weight 91.

1, the stirring vane 20 is formed with an inclined portion 21 inclined to be rounded upward or downward at an end portion thereof, and a length member 94 is provided at an end portion of the stirring blade 20 It is possible to prevent the rotating copper wire from being disturbed as much as possible.

Although the stirring vanes 20 adjacent to each other vertically restrict the length range of the length member 94 so that they are not struck by the weight 94, the scattering wings 40 provided on the spiral wings 30 adjacent to the inner wall surface, A weight may be generated by the weight 94.

Particularly, since the scattering vane 40 is rotatable while being slidably moved, if the scattering vane 40 to be rotated upward is hit by the weight 91, the rotation is not performed and thereby the scattering of the laundry is prevented Can cause.

As shown in FIGS. 2 and 3, the helical blade 30 is formed with an impact preventing jaw 31 protruding upwardly on the inner circumferential surface thereof so that the scattering blades 40 can be struck by the weight 91 as much as possible . ≪ / RTI >

The spiral stepped scattering dryer of the present invention having the above configuration is configured such that the heating medium is introduced into the space between the inner case 10 and the heating medium case 60 via the heating medium inlet pipe 61, Circulates along the passage 51, and then is discharged through the heating medium discharge pipe 62.

Through this process, the inner circumferential surface of the inner case 10 becomes a high temperature state, and the laundry in the inner case 10 is dried.

After the laundry is introduced into the inner case 10 through the supply pipe 13, the rotary shaft 11 is rotated by the operation of the driving motor 12 and the stirring blade 20 And the spiral wings 30 connected thereto are rotated.

At this time, the object to be dried loaded in the inner case 10 rises along the upper surface of the spiral blade 30 located below the inner case 10, and in this process, The drying object is brought into contact with the inner circumferential surface of the inner case 10 and dried while causing heat exchange with the inner circumferential surface of the inner case 10 at a high temperature.

Particularly, the object to be dried spreads thinly on the upper part of the spiral wing 30 and is lifted by the heat in the ascending process, and the weight is lightened and scattered.

Further, in the scattering state, the inter-particle distance becomes farther away, so that moisture is evaporated more easily and drying is performed.

The objects to be dried reaching the uppermost spiral blade 30 and scattered fall downward through the center side of the inner case 10. When reaching the lower end of the inner case 10, In this case, as the agitating blades 20 installed for connecting the helical blades 30 rotate a number of times in the middle, a rapid descent does not occur but a vortex is generated in the air and is delayed So that the evaporation of the water becomes better.

In this process, since the heating medium moves in the heating medium case 60 while rotating in a spiral manner along the heating medium passage 51, uniform distribution of the heating medium is achieved as compared with the conventional spiral drying apparatus, .

Particularly, in the upper part of the spiral wing 30, a scattering wing 40 arranged in a spiral shape on a rotating shaft 11 as a center is installed so as to protrude upwards, Scattering and descending are continuously repeated by colliding with the scattering wings 40. This causes evaporation of moisture while repeatedly scattering the objects to be dried before reaching the uppermost spiral blade 30, do.

As described above, the weight weight 91 constituting the striking device 90 is transferred to the agitating blades 20 (see FIG. 1), as shown in FIG. And rotates in an upward direction by a centrifugal force in a state of being perpendicular to the paper as viewed from the side, thereby hitting the inner circumferential surface of the inner case 10 to remove the scales attached thereto.

Since the length of the length member 94 is limited in this process, the weight pieces 91 adjacent to each other do not affect each other, so that the twisting of the length member 94 does not occur, and the upper and lower stirring blades 20, The damage is not caused.

Also, the impact preventing blade (31) does not damage the scattering vane (40) arranged on the spiral blade (30).

The blow through the weight weights 91 is also performed when the forward rotation, the rotational speed, and the rotational direction are changed continuously. In this process, the scattering wing 40, the stirring wing 20 Damage is prevented.

10: inner case 11: rotary shaft
12: drive motor 13: supply pipe
14: discharge pipe 20: stirring wing
21: inclined portion 30: helical wing
31: Striking prevention chin 40: Shattering wing
41: Round section 42: Resistance accommodating section
43: rotation pin 44: rotation pin insertion hole
50: helical step member 51: heating medium passage
60: Heat medium case 61: Heat medium inlet pipe
62: Heat medium discharge pipe 70: Insulation
80: Insulation case 90: Striking device
91: Weight weight 92: Sliding member
92a: Sliding hole 92b: Bolt tightening hole
93: fixing bolt 94: length member

Claims (5)

delete In the dryer,
And a driving motor connected to the rotating shaft 11 to rotate the rotating shaft 11 and capable of adjusting a speed and a rotating direction of the rotating shaft 11, An inner case 10 provided on an outer side of the upper portion;
One side of which is connected to the rotating shaft 11 and the other side is installed horizontally toward the inner wall surface of the inner case 10 and spaced apart from the inner wall surface, A plurality of agitating blades (20) arranged on the side surface and having a plurality of vertically spaced apart layers;
One side and the other side of which are connected to a stirring blade 20 which forms upper and lower adjacent layers and is formed in a spiral shape inclined up and down and is provided along the outer side of the stirring blade 20, A spiral wing 30 on which the spiral blade 30 is installed;
The spiral blade 30 has a round portion 41 which is upwardly protruded from the upper surface of the spiral blade 30 and has a spiral shape toward the rotary shaft 11 on a plane and is formed on one side in an upward direction And a resistance accommodating portion 42 is formed on the opposite side of the round portion 41 so as to be upwardly biased and the rotation pin 43 is inserted between the round portion 41 and the resistance accommodating portion 42 The rotation pin insertion hole 44 is curved in the same direction as the round portion 41 with a width larger than the diameter of the rotation pin 43, The wing 40 is configured so as to be able to move forward or backward with respect to the rotary pin 43. The rotary section 43 can be moved up or down as the rotary section 43 rotates about the rotary pin 43 (Not shown) of the laundry A scattering wing (40) for guiding scattering;
A spiral staircase member 50 which is provided in a spiral shape along the outer circumferential surface of the inner case 10 so as to be in contact with the outer circumferential surface of the inner case 10 and forms a heating medium passage 51 between upper and lower adjacent layers, ;
The heating medium inlet pipe 61 and the heating medium discharge pipe 62 are connected to one side and the other side respectively and the inner wall faces the other side of the helical step portion, (60);
A heat insulating material 70 surrounding the outer peripheral surface of the heating medium case 60;
A heat insulating case (80) enclosing an outer circumferential surface of the heat insulating material (70);
A length member 94 connected at one end to the stirring vanes 20 and freely rotatable from one connection point at the other side and a weight member 91 disposed at the other end of the length member 94, And the weight weight 91 strikes the inner wall surface of the inner case 10 in accordance with the rotation of the stirring vane 20, And a striking device (90) whose turning radius is shorter than the distance between the upper and lower stirring blades (20)
The length member 94 is formed with a sliding hole 92a through which the stirring vane 20 is inserted and is connected to a sliding member 92 moving along the stirring vane 20,
A bolt fastening hole 92b is formed at one side of the sliding member 92 and a fastening bolt 93 screwed to the bolt fastening hole 92b and the lower end of the sliding member 92 presses and fixes the stirring vane 20 . ≪ / RTI >
Spiral stepped scattering dryer with striking device.
3. The method of claim 2,
Characterized in that the stirring vane (20) is provided with an inclined portion (21) inclined to be rounded upward or downward at an end portion thereof.
Spiral stepped scattering dryer with striking device.
The method of claim 3,
Characterized in that the helical blade (30) is provided with an impact preventing blade (31) protruding upward in an inner peripheral surface thereof.
Spiral stepped scattering dryer with striking device.
5. The method according to any one of claims 2 to 4,
Characterized in that the weight (91) is made of soft material and is replaceable from the length member (94)
Spiral stepped scattering dryer with striking device.

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