KR101637001B1 - Device for removing yellow membrane of gizzard - Google Patents

Abstract

An apparatus for removing a proximal membrane according to an embodiment of the present invention includes: an operation member having a coupling hole and a guide hole; An eccentric shaft rotatably coupled to the coupling hole, the eccentric shaft allowing the actuating member to be operated by a rotational operation; And a fixed shaft coupled to the guide hole; .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a device for remodeling a proximal membrane,

The present invention relates to a proximal membrane removing apparatus provided in a device for processing a proximal chick.

In general, GIZZARD is also called a sand bag or a so-called "hen house". Chickens are destroyed by crushed grains or small stones that are ingested together with the grains fed or the tight food feed. Therefore, proximal muscles and muscles are well developed around this narrow role of center for this role. The shape is bulging like a convex lens, and the muscles are strong and hard, and the texture is very good, and it is popular as a processed food. However, processing of proximal chickens is done by hand. In particular, as the proximal membrane removal process, which is the next process of the proximal incision, proceeds manually, it is difficult to mass-process and the quality of the process deteriorates.

As an example, Korean Patent Laid-Open Publication No. 10-2007-0042523 discloses a " chicken proximal (chamomile) processing system ".

In order to solve the above-mentioned problems, an embodiment of the present invention is to provide a proximal membrane remover capable of automatically removing a membrane attached to a proximal portion of a chicken after proximal incision of a chicken.

According to an aspect of the present invention, there is provided an apparatus for removing a proximal membrane, comprising: an operation member having a coupling hole and a guide hole; An eccentric shaft rotatably coupled to the coupling hole, the eccentric shaft allowing the actuating member to be operated by a rotational operation; And a fixed shaft coupled to the guide hole; Wherein the distal end portion of the operating member is moved downwardly from the proximal feeding device by pressing the proximal end coupled to the proximal feeding device while being pressed against the releasing device located below the operating member, And the removing device may be a pair of left and right helical gears.

In addition, the operative member may be located near a proximal transfer device provided in the proximal processing device.

The guide hole may be formed in the rear of the operation member with a gap from the engagement hole, and may have a length longer than the diameter of the fixation shaft so that the operation member can move when the eccentric shaft rotates.

In addition, the operative member may be positioned at a lower portion of the proximal transfer device that transfers the proximal portion, and the forward upper surface of the operative member may be formed of an inclined surface that conforms to the proximal transfer device.

The distal end of the operating member may be provided with a pressurizing portion that presses the proximal portion separated from the proximal transporting device while pressing the proximal portion to be close to the removing device.

Further, the eccentric shaft can be rotated by transmitting the rotational force of the power generator.

The power generation device may be a motor.

Further, the eccentric shaft may be connected to the power generating device by the power transmission device or the power transmitting member that is installed in the shaft and rotated.

Further, the power transmitting device may be a sprocket, and the power transmitting member may be a chain.

In addition, a guide frame for guiding the proximal movement may be provided outside the proximal transfer device.

According to the proximal membrane removal apparatus according to the embodiment of the present invention, the membrane of the proximal tip of the chicken can be automatically removed after the proximal extension of the chickens.

In addition, each proximal is not affected by the size, shape, and surface appearance of the proximal furrows, and is able to effectively remove the omentum attached to the proximal medial side.

In addition, it is possible to provide a proximal membrane removing apparatus optimized for a proximal processing apparatus, such as a problem of remarkably lowering the merchantability when the proximal membrane is not completely removed.

1 is an installation state diagram of a proximal support device.
Figure 2 is an enlarged view of a proximal support device.
3 is a view showing an installation state of a proximal membrane removing apparatus according to a preferred embodiment of the present invention.
FIGS. 4 to 7 are views showing an operation state of a proximal membrane removing apparatus according to a preferred embodiment of the present invention.
8 is a plan view showing an installed state of a proximal membrane removing apparatus according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

A proximal membrane removal device 400 according to an embodiment of the present invention is installed in the proximal processing device 100 as the next process of the proximal support device shown in FIGS.

The proximal support device includes a support member 201, a hinge 204 provided under the support member 201, a linkage 202 extending to one surface of the support member 201, A plurality of proximal support members 200 including a plurality of proximal support members 203 are arranged on both sides of the proximal transfer device 102 provided in the proximal machining apparatus 100 on both left and right sides. The support member 201 is formed in a curved shape so as to cover the side surface of the proximal side 300. The hinge 204 with which the hinge shaft 204a is coupled is connected to the engaging member 206 and the engaging member 206 is engageable or detachable with the support frame 205 of the proximal machining apparatus 100. The proximal machining apparatus 100 may be provided with a proximal incision device 101 and a safety cover 103.

The apparatus for removing a proximal membrane according to an embodiment of the present invention 400 is an apparatus for removing a membrane of a stem, which is the next step of a proximal support apparatus. Hereinafter, the configuration of a proximal membrane removing apparatus 400 according to an embodiment of the present invention will be specifically described Explain.

3, the apparatus for removing proximal trough according to an embodiment of the present invention includes an operation member for pressing the proximal trough 300 in close contact with the removal device 107 while separating the transferred proximal 300 from the proximal transfer device 102, An eccentric shaft 421 coupled to the operation member 411, and a fixed shaft 422.

Specifically, the operation member 411 is installed to be positioned in the vicinity of the proximal transfer device 102 provided in the proximal machining apparatus 100. The operation member 411 includes a coupling hole 412 to which the eccentric shaft 421 is coupled and a guide hole 413 to which the fixed shaft 422 is coupled.

The coupling hole 412 is formed as a hole larger than the eccentric shaft 421 so that the eccentric shaft 421 can freely rotate. The guide hole 413 is spaced from the engaging hole 412 and is punched rearward of the engaging hole 412. The guide hole 413 is formed as a hole having a length longer than the diameter of the fixing shaft 422 so that the operation member 411 can move when the eccentric shaft 421 rotates. It is preferable that the vertical width of the guide hole 413 is a size corresponding to the fixed shaft 422.

The actuating member 411 is installed to be positioned below the proximal transfer device 102 that transfers the proximal 300. The front upper surface of the actuating member 411 is formed of an inclined surface 414 that conforms to the proximal transfer device 102.

A pressing portion 415 is provided at the tip of the operation member 411. The pressing portion 415 separates the transferred proximal portion 300 from the proximal transfer device 102 and urges the separated proximal portion 300 to come into close contact with the removal device 107. The stripping device 107 may be a helical gear. The removing apparatus 107 may be configured as a left-right pair.

The proximal portion 300 is brought into close contact with the removing device 107 by the pressing portion 415 and the foreign substance inside the proximal portion 300 is separated from the foreign substance. The proximal portion 300 is transferred while passing through the proximal incision device 101, and the cut portion is attached to the removal device 107, so that the foreign substances and the tin 301 are simultaneously removed.

The removed foreign matter and the tern (301) are washed away by the water pressure sprayed from the spray pipe. Although the tilting 301 is mostly removed by the tilting device 107 but the tilting 301 is not completely separated and the tilting 301 is pushed by the water pressure and the water pressure of the injection tube, ), The tern 301 is caught and completely falls off. The engaging portion 105 is located behind the operation member 411. [

As shown in FIG. 3, the eccentric shaft 421 is rotated by the rotational force of the power generator 104 such as a motor. The eccentric shaft 421 is connected to the power generating device 104 and rotated by the power transmitting device or the power transmitting member 124 that is axially installed. The eccentric shaft 421 is eccentric by an eccentric distance L. [ The power transmitting device may be a sprocket and the power transmitting member 124 may be a chain.

As shown in FIG. 8, when the power generator 104 is driven, the shaft connected to the power generator 104 rotates, and the first sprocket 121 installed on the shaft rotates. As the first sprocket 121 rotates, the proximal transfer device 102 engaged with the first sprocket 121 rotates.

Simultaneously, the second sprocket 122 engaged with the proximal transfer device 102 is rotated together with the first sprocket 121. The shaft provided with the second sprocket 122 is rotated by the rotation of the second sprocket 122.

The eccentric shaft 421 can rotate because the rear end of the shaft where the second sprocket 122 is installed and the sprocket at the rear end of the eccentric shaft 421 are connected by the power transmitting member 124 such as a chain. Thus, the rotational force of the power generator 104 is transmitted to the eccentric shaft 412 through the first sprocket 121 and the second sprocket 122.

A guide frame 106 is provided on the outer periphery of the proximal transfer device 102. The guide frame 106 serves to guide the movement of the proximal portion 300.

On the other hand, the proximal transfer device 102 is a ring-shaped chain. The proximal transfer device 102 sequentially passes through the first power transmitting device 121, the second power transmitting device 122, and the third power transmitting device 123.

The following describes the operation of the desulfurizer according to the embodiment of the present invention.

By driving the power generation device 104, the proximal feeding device 102 operates. The proximal 300 coupled to the proximal transfer device 102 passes through the proximal incision device 101 and is incised in the median region.

As shown in FIG. 3, the incision 300 is transferred to the proximal membrane remover 400 by the proximal transfer device 102. Proximal 300 moves to proximal membrane remover 400 with the incision site facing down.

The proximal portion 300 positioned in the proximal membrane removal section is removed from the proximal transfer device 102 by the operation of the operation member 411 and is brought into close contact with the removal device 107 to remove the membrane 301. [

The operation of the proximal membrane removal apparatus 400 is performed as shown in FIGS. In the initial state, the front end portion of the guide hole 413 is positioned on the fixed shaft 422 (see Fig. 4). When the eccentric shaft 421 is rotated 90 degrees, the substantially middle portion of the guide hole 413 is positioned on the fixed shaft 422, and the actuating member 411 is moved upward. When the eccentric shaft 421 is rotated 180 degrees, the rear end portion of the guide hole 413 is positioned with the fixed shaft 422, and the actuating member 411 is moved forward and downward (see FIG. 6). When the eccentric shaft 421 is rotated 270 degrees, the substantially middle portion of the guide hole 413 is positioned on the fixed shaft 422, and the operation member 411 is moved backward (see FIG. 7). When the eccentric shaft 421 rotates 360 degrees, the initial state is obtained again.

The proximal end 300 coupled to the proximal transfer device 102 is brought into close contact with the removal device 107 while being separated from the proximal transfer device 102 through the operation of the operation member 411 and the operation of forward and backward The bulge 301 of the proximal portion 300 can be removed. The portion directly in contact with the proximal portion 300 is the pressing portion 415 at the tip of the operation member 411. [ That is, the proximal portion 300 is separated from the proximal transfer device 102 and brought into close contact with the removal device 107 by a pressing portion 415 provided at the distal end of the operation member 411.

As shown in Fig. 8, the fixed shaft 422 becomes a fixed point when the operation member 411 operates. The eccentric shaft 421 can be rotated by being connected to the power generating device 104 by a plurality of power transmitting devices or power transmitting members 124. Specifically, the rotational force of the power generating device 104 is transmitted to the first power transmitting device 104, Is transmitted to the eccentric shaft (421) via the first power transmitting member (121), the second power transmitting device (122), and the power transmitting member (124).

As can be seen, the proximal membrane removal apparatus according to the embodiment of the present invention can automatically remove the membrane attached to the proximal portion of the chicken after incision of the proximal portion of the chicken. In addition, each proximal is not affected by the size, shape, and surface appearance of the proximal furrows, and is able to effectively remove the omentum attached to the proximal medial side. In addition, it is possible to provide a proximal membrane removal apparatus optimized for a proximal processing apparatus, such that the problem of remarkable drop in merchantability can be completely solved if the proximal membrane is not completely removed.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . 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.

100: proximal processing device 101: proximal incision device
102: proximal feeding device 103: safety cover
104: power generating device 105:
106: guide frame 107:
121: first power transmitting device 122: second power transmitting device
123: Third power transmission device 124: Power transmission member
200: proximal support member 201: support member
202: connecting rod 203: weight
204: hinge 204a: hinge shaft
205: support frame 206: engaging member
300: proximal 301:
400: proximal membrane remover 411: operative member
412: Coupling hole 413: Guide hole
414: slope surface 415:
421: eccentric shaft 422: fixed shaft
L: Eccentric distance

Claims (10)

An operation member having a coupling hole and a guide hole; An eccentric shaft rotatably coupled to the coupling hole, the eccentric shaft allowing the actuating member to be operated by a rotational operation; And a fixed shaft coupled to the guide hole; / RTI >
The distal end portion of the operating member is pressed down by the proximal feeding device while being separated from the proximal feeding device while being brought into close contact with the releasing device located below the operating member,
Wherein the removing device is a pair of right and left helical gears.
The method according to claim 1,
Wherein:
Wherein the proximal membrane removal device is located in the vicinity of a proximal transfer device provided in the proximal processing device.
The method according to claim 1,
The guide hole
Wherein the hole is formed at the rear of the actuating member with a gap between the engaging hole and a hole having a length longer than the diameter of the fixed shaft so that the actuating member can move when the eccentric shaft rotates. The method according to claim 1,
Wherein the actuating member is located at a lower portion of the proximal transfer device for transferring the proximal portion and the forward upper surface of the actuating member is formed of an inclined surface conforming to the proximal transfer device.
The method according to claim 1,
At the tip of the operating member,
Wherein the pressurizing unit is provided to press the transferred proximal portion from the proximal transfer device while pressing the separated proximal portion to adhere to the removal device.
The method according to claim 1,
The eccentric shaft
Wherein the rotational force of the power generator is transmitted and rotated.
The method of claim 6,
The power generation device includes:
Wherein the proton remnant removing device is a motor.
The method of claim 6,
The eccentric shaft
And connected to the power generating device by a power transmitting device or a power transmitting member to be rotated.
The method of claim 8,
Wherein the power transmitting device is a sprocket and the power transmitting member is a chain.
The method of claim 2,
And a guide frame for guiding the proximal movement is provided outside the proximal transfer device.

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