KR102581246B1 - Discharge density control device - Google Patents

Abstract

The present invention relates to a device for controlling the discharge density of a material feeding device for badges. More specifically, the present invention relates to a device for controlling the discharge density of a material feeding device, and more specifically, a feeding main body in which a hopper into which the material for badges is input is provided at the upper part of the conveying portion and a first flange is provided at the end of the conveying portion. ; A supply connection portion is provided with a second flange for coupling with the first flange on one side of the connection pipe portion, and has a coupling portion in which a plurality of fitting grooves are formed in a slit shape at the output side end of the connection pipe portion; A supply screw installed inside the above-mentioned supply main body and the supply connection portion so that one side is supported by a support bearing; A bearing housing that is coupled to the coupling portion to rotatably support the end of the feeding screw and increases the density of the discharged material; By configuring it, it is possible to expect a smooth supply of material while preventing deflection of the screw by supporting the end of the feed screw by combining the bearing housing with the coupling part provided at the end of the feed connection, and the outlet side of the bearing housing. It relates to a discharge density control device of a media material feeding device that can increase the density of the media material supplied by reducing the cross-sectional area.

Description

Discharge density control device of media material feeding device

The present invention relates to a device for controlling the discharge density of a material feeding device for badges. More specifically, the present invention relates to a device for controlling the discharge density of a material feeding device, and more specifically, a feeding main body in which a hopper into which the material for badges is input is provided at the upper part of the conveying portion and a first flange is provided at the end of the conveying portion. ; A supply connection portion is provided with a second flange for coupling with the first flange on one side of the connection pipe portion, and has a coupling portion in which a plurality of fitting grooves are formed in a slit shape at the output side end of the connection pipe portion; A supply screw installed inside the above-mentioned supply main body and the supply connection portion so that one side is supported by a support bearing; A bearing housing that is coupled to the coupling portion to rotatably support the end of the feeding screw and increases the density of the discharged material; By configuring it, it is possible to expect a smooth supply of material while preventing deflection of the screw by supporting the end of the feed screw by combining the bearing housing with the coupling part provided at the end of the feed connection, and the outlet side of the bearing housing. It relates to a discharge density control device of a media material feeding device that can increase the density of the media material supplied by reducing the cross-sectional area.

In general, mushrooms are cultivated through the following processes: preparation of medium materials, water hydration, sterilization, seed planting, medium colonization, mushroom harvesting, and medium disposal. Among the many requirements to increase the success rate of mushroom cultivation, the most important is the medium.

The success rate of mushroom cultivation varies greatly depending on the moisture absorption and sterilization effect of the medium.

The media material feeding device is used to compress and feed the media material to have a predetermined density while stirring it, so that the media can be manufactured into a desired shape in a later process.

However, in the conventional media material feeding device, it was difficult to balance the rotation of the rotating screw because most of the material transfer screws were supported by bearings only on one side where the material was supplied, and the solid media material supplied through the screw was difficult to achieve. There was a problem that it could not be transported smoothly, and as the length of the screw's rotation axis became longer, the end of the screw sagged, causing damage due to eccentricity or load concentration of the support bearing.

In addition, in the prior art, since the outlet side of the feeding device is open, when discharging the material, the material is concentrated and discharged only at the inner lower part of the outlet side, resulting in a problem in which the density of the discharged material is not output evenly.

Therefore, in the past, there was a problem of not being able to control the size of the mushroom medium produced by flowing out through the outlet of the feeding device.

* Prior art literature *

Republic of Korea Patent Application No. 10-2019-0176867

Republic of Korea Utility Model Application No. 20-2008-0012090

Accordingly, the present invention to solve the above problem includes a feeding main body in which a hopper into which material for discharging is input is provided at the upper part of the conveying portion and a first flange is provided at the end of the conveying portion; A supply connection portion having a second flange for coupling with the first flange on one side of the connection pipe portion, and a coupling portion having a plurality of fitting grooves formed in a slit shape at the output side end of the connection pipe portion; A supply screw installed inside the above-mentioned supply main body and the supply connection portion so that one side is supported by a support bearing; A bearing housing that is coupled to the coupling portion to rotatably support the end of the feeding screw and increases the density of the discharged material; By configuring it, a smooth supply of material can be expected while preventing deflection of the screw by supporting the end of the feeding screw by combining the bearing housing with the coupling part provided at the end of the feeding connection, and the outlet side of the bearing housing. The purpose is to provide a discharge density control device for a media material feeding device that can increase the density of the media material supplied by reducing the cross-sectional area.

The present invention for achieving the above purpose is

A feeding body unit (1) in which a hopper (12) into which the material for discharging is input is provided at the upper part of the transfer unit (11) and a first flange (13) is provided at the end of the transfer unit (11);

A supply connection part (2) provided with a second flange (22) on one side of the connection pipe part (21) for being coupled to the first flange (13);

A supply screw (3) installed inside the above-described supply main body (1) and the supply connection portion (2) so that one side is supported by a support bearing (7.8); In the discharge density control device of the medium material feeding device comprising,

At the output side end of the connector portion 21, a coupling portion 23 is formed in which a plurality of fitting grooves 24 are formed in a slit shape,

It is characterized by further including a bearing housing (4) that is coupled to the coupling portion (23) to rotatably support the end of the feed screw (3) and increases the density of the discharged material.

According to the present invention, it is possible to expect smooth supply of material while preventing sagging of the screw by supporting the end of the feeding screw by coupling the bearing housing to the coupling portion provided at the end of the feeding connection, and forming the feeding screw on the feeding screw. By widening or narrowing the gap on the outlet side of the transfer blades, the fixed quantity supply of media material can be maintained stably, and by reducing the cross-sectional area of the outlet side of the bearing housing, the effect of increasing the density of the supplied media material is achieved. You can expect it.

Figure 1 is a cross-sectional view showing a material supply device for badges to which the discharge density control device of the present invention is applied.
Figure 2 is an exploded view showing the supply connection and bearing housing applied to the present invention.
Figure 3 is a view showing the combined state of the supply connection and bearing housing applied to the present invention.
Figure 4 is a diagram showing the main structure of the present invention.
Figure 5 is a view showing an embodiment of the feeding screw applied to the present invention.
Figure 6 is a diagram showing a first embodiment of a bearing housing applied to the present invention.
Figure 7 is a diagram showing a second embodiment of the bearing housing applied to the present invention.
Figure 8 is a view showing a third embodiment of the bearing housing applied to the present invention.
Figure 9 is a diagram showing a fourth embodiment of a bearing housing applied to the present invention.
Figure 10 is a view showing a fifth embodiment of the bearing housing applied to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the attached drawings FIGS. 1 to 10.

According to the drawing, the present invention,

A feeding body unit (1) in which a hopper (12) into which the material for discharging is input is provided at the upper part of the transfer unit (11) and a first flange (13) is provided at the end of the transfer unit (11);

A supply connection part (2) provided with a second flange (22) on one side of the connection pipe part (21) for being coupled to the first flange (13);

A supply screw (3) installed inside the above-described supply main body (1) and the supply connection portion (2) so that one side is supported by a support bearing (7.8); In the discharge density control device of the medium material feeding device comprising,

At the output side end of the connector portion 21, a coupling portion 23 is formed in which a plurality of fitting grooves 24 are formed in a slit shape,

It is characterized by further including a bearing housing (4) that is coupled to the coupling portion (23) to rotatably support the end of the feed screw (3) and increases the density of the discharged material.

In addition, the bearing housing (4) is

The housing body 41 is provided with an installation groove 42 for installing the support bearing 9 at one end, and an insertion groove 24 formed on the coupling portion 23 is provided on the outer periphery of the housing body 41. A plurality of coupling wings 43 for fitting and coupling are formed to protrude, and the support bearing 9 installed in the installation groove 42 is configured to support the end of the rotation axis 31 of the feeding screw 3. .

In addition, the outer diameter of the housing body 41, which forms the bearing housing 4, is formed with a tapered portion 44 formed to increase the diameter of the taper toward the outlet side, so that the space between the housing body 41 and the coupling portion 23 is narrow. It is characterized by increasing the density of the material discharged as it melts.

In addition, a diameter reduction portion 45 is formed at the end of the bearing housing 4 to increase the density of the discharged material.

In addition, the thickness of the coupling portion 23 where the bearing housing 4 is coupled is formed to be thicker than the connector portion 21, so that the space between the housing body 41 and the coupling portion 23 narrows and the density of the discharged material increases. It is characterized by being structured as follows.

In addition, the thickness of the coupling wings 43 forming the bearing housing 4 is configured to become thicker toward the rear end of the wing (43a), or the density of the discharged material is increased by increasing the number of coupling wings 43. It is characterized by

The discharge density control device of the material feeding device for badges of the present invention is composed of a feeding body part (1), a feeding connection part (2), a feeding screw (3), and a bearing housing (4), and the solid form input into the hopper (12) The material is transported to the outlet side and discharged by stirring and compressing.

The feeding body part 1 is provided with a cylindrical transfer part 11, and a hopper 11 for inputting the material is formed at the top of the transfer part 11, and a first flange for coupling is provided at the end of the transfer part 11 ( 13) is formed.

The supply connection part (2) is coupled to the above-mentioned supply main body part (1) to form the external shape of a supply device. The supply connection part (2) is provided with a connector part (21) for communicating with the transfer part (11). A second flange 22 is formed on one side of the connector 21 to be coupled to the first flange 13.

And on the outlet side of the connecting pipe part 21, a coupling part 23 is formed in which a plurality of fitting grooves 24 are formed in a slit shape.

The feeding screw (3) is rotatably installed in the above-described feeding main body (1) and the feeding connection part (2) to compress and transfer the material introduced into the hopper (12) while stirring it to the outlet side. The feeding screw (3) is a rotating shaft. It is constructed by forming transfer wings (32) in a spiral shape on the outer peripheral surface of (31).

When installing the feeding screw (3), one side of the rotating shaft (31) is supported by the support bearings (7, 8) installed in the conveying part (11), and the other side of the rotating shaft (31) is coupled to the coupling portion (23). It is supported on the support bearing (9) installed in the bearing housing (4).

The rotation shaft 31 is connected to an externally installed drive motor 5 and a chain 6, and the rotation shaft 31 rotates with the rotational power of the drive motor 5.

In addition, in the present invention, the gap between the transfer wings 32 forming the feed screw 3 can be variably widened or narrowed depending on the physical properties of the material being transferred.

Figure 5a shows an embodiment in which the transport wings 32 are formed at equal intervals on the rotation axis 31, and Figure 5B shows the shape of the transport wings 32 on the rotation axis 31 compared to the first half (section A). It shows an embodiment in which the gap between the transfer blades 32 in the latter half (section B) is formed to be widened, and Figure 5c shows that when forming the transfer blades 32 on the rotation axis 31, the latter half (section A) is larger than the front half (section A). This shows an embodiment in which the spacing between the transfer blades 32 in section B is narrowed.

If the physical properties of the material are soft, it is desirable to narrow the formation gap between the transfer wings 32 as shown in Figure 5c to ensure stable transfer of the material, and if the material's physical properties are hard, transfer as shown in Figure 5b. It is desirable to widen the formation interval of the wings 32 so that the material can be transported stably.

On the other hand, the bearing housing (4) is for supporting the end of the rotating shaft (31) of the feeding screw (3), and has a housing body (41) with an installation groove (42) formed at one end for installing the support bearing (9). It is provided with a support bearing installed in the installation groove 42, and a plurality of coupling wings 43 are formed to protrude on the outer periphery of the housing body 41 to be fitted and coupled to the fitting groove 24 formed in the coupling portion 23. (9) is configured to support the end of the rotating shaft (31) of the feeding screw (3).

When coupling the bearing housing 4 to the coupling portion 23, the coupling wing 43 can be welded while being inserted into the fitting groove 24.

At this time, it is revealed that the coupling wings 43 can be welded and joined to the inner peripheral surface of the bearing housing 4.

In addition, it is revealed that the bearing housing (4) can be welded to the end of the supply connection portion (2).

If the bearing housing (4) is coupled to the coupling portion (23) so that the support bearing (9) rotatably supports the end of the rotating shaft (31), sagging of the feeding screw (3) is prevented and stable material supply is expected. It becomes possible.

In addition, in the present invention, the density of the material discharged using the bearing housing (4) and the size of the mushroom medium produced by flowing out through the bearing housing (4) can be controlled.

In Figure 6, a tapered portion 44 is formed so that the outer diameter of the housing body 41 forming the bearing housing 4 is increased toward the outlet side, so that the space between the housing body 41 and the coupling portion 23 is formed. A first embodiment is shown in which the density of the discharged material increases as the narrowing becomes narrower.

That is, by forming the housing main body 41 to be tapered and enlarged toward the outlet end, the gap between the bearing housing 4 and the housing main body 41 is narrowed, thereby allowing the bearing housing 4 to pass through the housing body 41. Not only can it increase the density of the leaked material, but it can also control the size of the mushroom medium produced.

Figure 7 shows a second embodiment in which a diameter reduction portion 45 is formed at the end of the coupling portion 23 to increase the density of the discharged material.

If a tapered diameter reduction portion 45 is formed at the end of the coupling portion 23 as shown in Figure 7, the space between the coupling portion 23 and the housing body 41 narrows, thereby increasing the density of the discharged material. You can control the size of the mushroom medium by giving it.

In Figure 8, the thickness of the coupling portion 23 where the bearing housing 4 is coupled is formed to be thicker than the connector portion 21, so that the space between the housing body 41 and the coupling portion 23 narrows, and the density of the discharged material increases. A third embodiment configured to be high is shown.

Figure 9 shows a fourth embodiment in which the thickness of the coupling wings 43 forming the bearing housing 4 is configured to become thicker toward the rear end of the wing (43a), and in Figure 10, the number of coupling wings 43 is increased. A fifth embodiment configured to increase the density of the ejected material is shown.

By gradually increasing the thickness of the coupling blades (43) toward the rear end of the wing (43a), the gap between the coupling blades (43) is gradually reduced, and as a result, the material flows out through the bearing housing (4). Not only can it increase the density, but it can also control the size of the mushroom medium produced.

That is, the first to fifth embodiments of the bearing housing 4 increase the density of the material passing through the bearing housing 4 to ensure stable discharge of the badge material.

1: Delivery main body, 2: Delivery connection unit,
3: feed screw, 4: bearing housing,
5: drive motor, 6: chain,
11: transfer unit, 12: hopper,
13: first flange, 21: connector part,
22: second flange, 23: coupling portion,
24: Fitting groove, 31: Rotating shaft,
32: transfer wing, 41: housing body,
42: Installation groove, 43: Combined wing,
44: Taper part, 45: Diameter reduction part,
43a: rear end of wing, 7, 8, 9: support bearing,

Claims (6)

A feeding body unit (1) in which a hopper (12) into which material for discharging is input is provided at the upper part of the transfer unit (11) and a first flange (13) is provided at the end of the transfer unit (11);
A supply connection part (2) provided with a second flange (22) on one side of the connection pipe part (21) for being coupled to the first flange (13);
A supply screw (3) installed inside the above-described supply main body (1) and the supply connection portion (2) so that one side is supported by a support bearing (7.8); In the discharge density control device of the medium material feeding device comprising,
At the output side end of the connector portion 21, a coupling portion 23 is formed in which a plurality of fitting grooves 24 are formed in a slit shape,
It further includes a bearing housing (4) that is coupled to the coupling portion (23) to rotatably support the end of the feeding screw (3) and increases the density of the discharged material,
The bearing housing (4) is
The housing body 41 is provided with an installation groove 42 for installing the support bearing 9 at one end, and an insertion groove 24 formed on the coupling portion 23 is provided on the outer periphery of the housing body 41. A plurality of coupling wings 43 for fitting and coupling are formed to protrude, and the support bearing 9 installed in the installation groove 42 is configured to support the end of the rotation axis 31 of the feeding screw 3. Discharge density control device for media material feeding device.
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