JP6148040B2 - Food production equipment - Google Patents

Description

The present invention relates to meat products such as croquettes and cheese in hamburgs, and further to food production apparatuses such as buns and confectionery breads. More specifically, a nozzle device and a shutter device can be easily attached to and detached from a drive unit, and jet water The present invention relates to a food production apparatus that can be washed with water.

The food manufacturing apparatus, for example, arranges a plurality of polymerization nozzle devices at an upper position of the conveying device, and interposes the polymerization nozzle device between the conveying screw device for the inner packaging material and the outer material for the outer covering material in the conveying direction of the conveying device. In the configuration in which the transfer screw device is disposed, a casing is connected to each of the transfer screw devices for the inner packaging material and the outer skin material, a plurality of vane pumps are provided in each casing, and the discharge port is provided in each vane pump. There is a wrapping machine provided on the opposite side of the inlet from the transfer screw device.

The wrapping machine includes a shutter device between the upper and lower sides of the superposition nozzle device and the transport device. The shutter device includes a shutter opening formed by being surrounded by a plurality of shutter pieces so as to be freely opened and closed, and moves up and down in conjunction with the opening and closing operation. Then, the shutter device closes the opening while lowering the shutter piece so as not to hinder the flow of the rod-shaped food dough continuously discharged from the superposition nozzle device, and the shutter device closes the opening from the rod-shaped food dough. Divide Sano's food. Moreover, the conveyance surface of the conveyance device located below the superposition nozzle device moves up and down in conjunction with the vertical movement of the shutter device (for example, Patent Document 1).

In addition, the superposition nozzle device is provided with a stepped arrangement portion on a base portion provided in the main body frame of the wrapper, for example, and the lower outer cylinder portion, the stirring rotary body and the upper outer cylinder portion are arranged in one direction. It is provided so that it can be attached to and detached from. In addition, the base portion includes a rotating gear body that rotatably supports the stirring rotating body, and includes a bearing seal portion that suppresses intrusion of cloth and the like into the bearing portion that supports the rotating gear body ( For example, Patent Document 2).

Another food manufacturing apparatus is a wrapping machine in which a shutter device is arranged without moving up and down below a polymerization nozzle device. The wrapping machine intermittently feeds the inner packaging material into the outer skin material, thereby interspersing the inner packaging material inside the rod-shaped food dough discharged from the polymerization nozzle device, and intermittently drops the flow rate of the rod-shaped food dough. It is an apparatus that divides the food to be encapsulated by changing it (for example, Patent Document 3).

JP 2002-238441 A Republished patent number WO2003 / 094620 Japanese Utility Model Publication No. 62-86887

When manufacturing food, thorough hygiene management is indispensable, and the food manufacturing apparatus according to the above-mentioned patent literature also performs washing with running water. However, in particular, in an apparatus for producing food using meat, it has been strongly desired that washing with high-pressure water such as jet water is possible for the purpose of improving work efficiency and cleaning effect.

The polymerization nozzle devices described in Patent Document 1 and Patent Document 2 have a problem in cleaning work because there is a difficulty in cleaning and drying because a stepped arrangement portion remains in the base portion. In addition, a bearing seal portion is attached to the rotating gear body remaining in the base portion. However, cleaning with jet water may infiltrate water from the outside into the base portion, and is not suitable for cleaning with jet water. There is a problem.

Moreover, the wrapper described in Patent Document 1 includes a shutter device that can move up and down with respect to the superposition nozzle device. The shutter device has to be provided with a vertical mechanism, and there is a problem that the whole food manufacturing apparatus becomes complicated. Further, when assembling the food production apparatus from each component, there is a problem that it takes time to assemble the center of the discharge port of the polymerization nozzle device and the center of the opening formed by the shutter piece of the shutter device. . Furthermore, when using the said foodstuff manufacturing apparatus, when the center of the said superposition | polymerization nozzle apparatus and the said shutter apparatus shifts, there exists a problem that it has to align again.

Further, the packaging machine described in Patent Document 3 is not suitable for a large amount of discharge because the inner packaging material must be intermittently supplied into the outer skin material although the shutter device does not move up and down. Furthermore, after the shutter piece of the shutter device is swung to shift the shutter opening from the open state to the closed state, the shutter piece is swung in the opposite direction so as to return to the open state again. The rotation must be stopped once, and before and after the stop, the shutter pieces gathered near the center of the shutter opening tend to hinder the flow of the rod-shaped food dough. There is a problem that there is a limit to the number of products produced. Further, like the packaging machine described in Patent Document 1, there is a problem in that it is necessary to align the centers of the superposition nozzle device and the shutter device.

The present invention has been made in view of the conventional problems as described above, and has a nozzle device for continuously extruding a rod-shaped food dough and a plurality of shutter pieces, and the shutter pieces are formed by surrounding the shutter pieces. A food manufacturing apparatus provided with a shutter device for dividing a divided dough of a required size from a rod-shaped food dough by opening and closing an opening, wherein the rod-like drive box is equipped with a rotation drive mechanism of the shutter device. comprising a communicating hole penetrating in the vertical direction food dough flows down, with the nozzle device detachably to the upper surface of the drive box with provided fixably in place by inserting from above the communication hole, the nozzle device comprises a rotary body rotating therein, above the drive box, detachably provided with a drive gear for the rotary member and meshing with the drive gear axis of rotation, the shutter A plurality of shutter pieces of the apparatus are arranged below the drive box, and are detachably provided on a shutter rotation shaft connected to the rotation drive mechanism without moving up and down relative to the drive box. is there.

Further, the drive box is characterized in that a rotation drive mechanism interlocked with the rotating body is housed therein.

Further, the shutter device is a rotary shutter having a shutter piece rotatable in one direction or a swinging shutter having a reciprocatingly rotatable shutter piece.

Further, the rotation drive mechanism of the shutter device and / or the rotation drive mechanism of the nozzle device incorporated in the drive box includes a shutter rotation shaft coupled to the plate member by rotating the plate member eccentrically, A gear rotating shaft that fixes a driving gear meshing with a rotating body of the nozzle portion is rotated.

According to the present invention, it is not necessary to provide a step-like arrangement portion in the portion where the nozzle device is attached to the drive box of the shutter device, and it can be formed in a surface shape without unevenness, so that cleaning and drying are easy. Yes. Furthermore, since the drive box does not have a built-in rotating gear body that is linked to the nozzle device, the drive box is hermetically sealed and can be cleaned with high-pressure water such as jet water, improving the efficiency of the cleaning operation. it can.
In addition, since the nozzle device and the shutter device can be integrally attached to and detached from the drive box, the center of the nozzle device and the center of the shutter opening formed by the plurality of shutter pieces can be prevented from being misaligned. The problem of having to adjust the alignment can be solved.

It is front explanatory drawing which shows the whole structure of the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention. It is plane explanatory drawing which shows the whole structure of the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention. It is side explanatory drawing which shows the whole structure of the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention. It is explanatory drawing by the cross section which shows the structure of the principal part with which the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention was equipped. It is explanatory drawing by the cross section which shows the structure of the principal part with which the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention was equipped. It is explanatory drawing by the cross section which shows the structure of the principal part with which the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention was equipped. It is explanatory drawing which shows operation | movement of the shutter apparatus 6 with which the foodstuff manufacturing apparatus 1 which concerns on the 1st Embodiment of this invention was equipped. It is explanatory drawing which shows operation | movement of the shutter apparatus 6 with which the foodstuff manufacturing apparatus 1 which concerns on the 2nd Embodiment of this invention was equipped.

A food production apparatus 1 according to a first embodiment of the present invention will be described with reference to FIGS. In the first embodiment, description will be given based on the case where two rows of encapsulated food (divided food) P including the second food D2 inside the first food D1 are manufactured simultaneously. The food production apparatus 1 includes a main body frame 2 made of square wood, and the main body frame 2 includes a first food material feeding device 3, a second food material feeding device 4, a superposition nozzle device 5, a shutter device 6, and a conveyance. A device 7 and a control device 8 are provided. Here, the direction orthogonal to the horizontal direction when the conveying direction F of the conveying device 7 is pointed is referred to as the width direction or the left-right direction in a similar sense (see FIG. 2).

Since the first food feeding device 3 and the second food feeding device 4 have the same configuration, the first food feeding device 3 will be mainly described. A vertical hopper 11 that accommodates the first food material D1, a ribbon-type rotary screw 12 that is rotatable within the hopper 11 (see the second food material feeder 4 shown on the right side of FIG. 2), and the rotary screw 12 The first food material that is transferred from the upper side to the lower side by the rotation of the nozzle 13 is sucked and communicated with the two sets of pumps 13 and the hopper 11 that are fed to the superposition nozzle device 5, and the rotary screw 12 and the pump 13 are freely rotatable. The housing 14 is supported. Each pump 13 can be selected from a vane pump, a gear pump, and the like. In this embodiment, a three-leaf root pump is adopted and arranged at the same distance from the rotation center of the rotary screw 12 in plan view. Further, the first food feeding device 3 includes a drive unit 15 including a drive mechanism for rotating the rotary screw 12 and the pump 13. The drive unit 15 includes a drive box 16 to which a control motor M1 for driving the rotary screw 12 via a known gear train and a control motor M2 for driving the pump 13 via another gear train are mounted. . The housing 14 is detachably fixed to the upper surface of the drive box 16. The drive box 16 is detachably mounted on the left and right upper frames 2A of the main body frame 2 (see FIG. 2).

Further, the second food material feeding device 4 has the same configuration as the first food material feeding device 3, and the second food material D 2 is accommodated in the hopper 11, and the second food material D 2 is stored in the rotary screw 12 and the pump 13. Is fed to the superposition nozzle device 5 and is provided on the opposite side of the first food feed device 3 with the superposition nozzle device 5 in between.

4 and 5 are explanatory views for explaining the configuration of the superposition nozzle device 5, the drive unit 21, and the shutter device 6, and show a longitudinal sectional view in a front view. Further, FIG. 5 is an explanatory view showing a state in which the superposition nozzle device 5 and the shutter device 6 are detached from the drive unit 21. FIG. 6A is an explanatory diagram in plan view schematically illustrating the inside of the driving unit 21. FIG. 6B schematically illustrates the inside of the driving unit 21 with the driving unit 21 as a main part. It is explanatory drawing by the longitudinal cross section seen from the side demonstrated.

The superposition nozzle devices 5 are arranged in two rows on the left and right sides of a drive box 22 of a drive unit 21 attached to the main body frame 2 along the width direction. The superposition nozzle device 5 can be placed from the upper surface of the drive box 22 and is provided integrally with the shutter device 6 fixed to the drive box 22. The drive box 22 is joined to the upper box body 22A and the lower box body 22B through a sealing member such as round rubber or an O-ring, and further by applying a sealing coating material so as to overlap each other. Further, the drive box 22 is provided with two communication holes 23 into which the superposition nozzle device 5 is fitted and from which the bar-shaped food dough D extruded from the superposition nozzle device 5 flows down. The communication hole 23 is a hollow portion of the pipe member 24 provided with two flange portions 24A and 24B in the vertical direction. By fitting the upper and lower pipe portions of the pipe member 24 to the upper box body 22A and the lower box body 22B, respectively, the upper box body 22A and the lower box body 22B are aligned in the horizontal direction, and the fitting portion Sealing is used to prevent water from entering the drive box 22.

The superposition nozzle device 5 includes an inner cylinder portion 37 that is arranged concentrically with the outer cylinder portion 31. The outer cylinder part 31 includes an upper outer cylinder part 32 and a lower outer cylinder part 33, and a rotating body 34 is rotatably provided between the upper and lower outer cylinder parts 32, 33. The lower outer cylinder portion 33 includes an outer nozzle holder 35 and an outer nozzle base 36 screwed to the outer nozzle holder 35 so as to be detachable and replaceable.

The inner cylinder portion 37 forms a flow path through which the second food material D2 fed from the second food material feeding device 4 flows down, and is attached to and detached from the upper inner cylinder portion 38 and the upper inner cylinder portion 37. An inner nozzle base 39 that is freely screwed is provided. The upper inner cylinder portion 38 is detachably attached to the upper outer cylinder portion 32 with a nut member 40. And between the outer cylinder part 31 and the inner cylinder part 37, the cyclic | annular space part 41 as a flow path through which the 1st foodstuff D1 sent from the said 1st foodstuff feeding apparatus 3 flows down is formed. . Therefore, the superposition | polymerization nozzle apparatus 5 continuously extrudes the rod-shaped foodstuff D which coat | covered the outer periphery of the 2nd foodstuff D2 concentrically with the 1st foodstuff D1 from the said outer nozzle mouthpiece 36 which is a discharge outlet.

The rotating body 34 includes a stirring rotating body 43 including a stirring body 42 that stirs the first food D1 flowing down the annular space 41, and a rotating gear body 44 that detachably engages the stirring rotating body 43. Yes. The rotating gear body 44 is rotatably held by a holding portion 45 provided outside the outer cylinder portion 31. The holding portion 45 includes a pair of thrust bearings 46 that sandwich the flange portion of the rotating gear body 44 from above and below, and includes a base holder 47 that supports the lower thrust bearing 46. The base holder 47 is annular as a whole, and further includes an annular protrusion 47A on the inner lower surface. The base holder 47 is placed on the upper surface of the drive box 22 by fitting the protrusion 47A into the communication hole 23 of the drive unit 15. Further, the base holder 47 is detachably engaged with the outer nozzle holder 35 of the lower outer cylinder portion 32 inside thereof.

In addition, the holding portion 45 includes an outer holder 48 that holds the upper and lower thrust bearings 46 from the outside and fits with the base holder 47. Three cutting arms 51 are provided on the outer periphery of the lower part of the outer holder 48, and three engagement pins 52 corresponding thereto are provided upright on the upper surface of the drive box 22. By rotating the outer holder 48 in the horizontal direction in a state where it is placed on the upper surface of the drive box 22, the cuts of the cut arms 51 are engaged with the engagement pins 52, respectively, and a disk-like shape formed on the top of the engagement pins. The outer holder 48 is fixed to the drive box 22 without being pulled upward by the flange portion pressing the upper surface of the cutting arm. Further, by fixing the outer cylinder part mounting tool 49 to the upper part of the outer holder 48 and locking the locking part 50 provided protruding from the center outer side of the upper outer cylinder part 32 from above with the outer cylinder part mounting tool 49. The entire superposition nozzle device 5 is fixed to the drive box 22. The positioning of the superposition nozzle device with respect to the drive box 22 is performed by engaging the notch of the notch arm 51 with the engagement pin 52 without fitting the protrusion 47A and the communication hole 23. Is also possible. Further, a pin (for example, two cylindrical pins or an oval pin such as a key material) is erected on the upper surface of the drive box 22, and a hole is formed in the lower surface of the base holder 47 so as to correspond to the pin. It is possible to use various kinds of positioning means such as

Here, the rotation drive mechanism of the rotating body 34 will be described. A drive gear 53 that meshes with the rotating body 34 is provided in the vicinity of the superposition nozzle device 5 on the upper surface side of the drive box 22 (see FIGS. 4 to 6). The drive gear 53 is detachably provided on the upper portion of the main shaft 54A of the gear rotation shaft 54 protruding from the upper surface of the drive box 22, and is fixed by a nut member. The lower portion of the main shaft 54A of the gear rotation shaft 54 is pivotally attached to the upper box 22A via a bearing 55 and further via a seal member such as an oil seal. In the drive box 22, an eccentric shaft 54B that is eccentric with respect to the main shaft 54A is provided below the gear rotation shaft 54. A plate member 57 is attached to the eccentric shaft 54B via a bearing 56 so as to be eccentrically rotatable in the horizontal direction.

Further, a control motor M3 for eccentrically rotating the plate member 57 is attached to the lower surface of the end portion (right side in FIG. 6A) of the lower box body 22B of the drive box 22. The main shaft 58A of the plate rotation shaft 58 is fixed to the rotation output shaft of the control motor M3. Further, an eccentric shaft 58B that is eccentric with respect to the main shaft 58A is provided on the upper portion of the plate rotation shaft 58. The eccentric shaft 58B has a plate member 57 attached thereto via a bearing 56 so as to be eccentrically rotatable. A rotating shaft 59 is rotatably provided on the inner lower surface (ceiling board) of the upper box 22A. The rotating shaft 59 includes an upper main shaft 59A and a lower portion including an eccentric shaft 59B that is eccentric with respect to the main shaft 59A. The main shaft 59A of the rotary shaft 59 is supported by the upper box 22A via a bearing 60, and the eccentric shaft 59B is attached to the plate member 57 via a bearing 56. The eccentric amounts of the main shafts and the eccentric shafts of the gear rotating shaft 54, the plate rotating shaft 58, and the rotating shaft 59 are the same. By rotating the plate member 57 supported in this manner eccentrically by the control motor M3, the respective gear rotating shafts 54 are rotated in conjunction with each other, and the rotating bodies 34 of the respective superposition nozzle devices 5 are rotated through the respective driving gears 53. To do.

Two sets of shutter devices 6 are provided along the width direction so as to correspond to the superposition nozzle device 5. Each shutter device 6 is provided with a detachable shutter piece 62 below the main shaft 61A of the four shutter rotation shafts 61 projecting downward from the lower surface of the drive box 22, and is fixed by a nut member. The upper parts of the main shafts 61A of the rotary shafts 61 are rotatably attached to the lower box body 22B of the drive box 22 via bearings 64 and seal members such as oil seals. It arrange | positions at equal intervals on the periphery centering on the communicating hole 23. FIG. The four shutter pieces 62 surround the shutter opening 63 so that the shutter opening 63 can be opened and closed. As described above, since the superposition nozzle device 5 can be positioned and attached to the drive box 22 on which the shutter rotation shaft 61 is disposed, the center of the superposition nozzle device 5 (synonymous with the center of the discharge port) and the shutter opening 63 are arranged. It becomes possible to match the center with the same axis.

In the shutter piece 62, two identically shaped cutting blades 68 and a cutting blade 69 are provided symmetrically with respect to the rotation center axis of the main shaft 61A of the shutter rotation shaft 61. Each cutting blade 68 and cutting blade 69 have a required thickness, and when the shutter opening 63 is closed, the first food material D1 wraps the second food material by applying a surface pressure to the rod-shaped food dough D. However, a convex surface 68A and a convex surface 69A are formed as working surfaces for cutting the rod-shaped food dough D, and a concave surface 68B that enables rotation of the shutter piece 62 on the opposite side of the cutting blade 68 through the tip of the cutting blade 69, A concave surface 69B is formed. Further, the tips of the cutting blades 68 and the cutting blades 69 are configured to contact the adjacent convex surfaces 68A and 69A when the shutter piece 62 rotates. Therefore, when the shutter rotation shaft 61 is rotated once, the shutter opening 63 formed by surrounding the shutter piece 62 opens and closes twice, and the shutter device 6 performs the cutting operation twice (see FIG. 7). ).

Here, the rotation mechanism of the shutter piece 62 will be described. Each shutter rotation shaft 61 includes an eccentric shaft 61B that is eccentric with respect to the main shaft 61A. Inside the drive box 22, a plate member 66 is attached to the eccentric shaft 61B via a bearing 65 so as to be eccentrically rotatable in the horizontal direction. A control motor M4 for eccentrically rotating the plate member 66 is attached to the lower surface of the end portion (right side in FIG. 6A) of the lower box body 22B of the drive box 22. The main shaft 67A of the plate rotation shaft 67 is fixed to the rotation output shaft of the control motor M4. In addition, an eccentric shaft 67B that is eccentric with respect to the main shaft 67A is provided on the upper portion of the plate rotation shaft 67. The eccentric shaft 67B has a plate member 66 attached thereto via a bearing 65 so as to be eccentrically rotatable. The eccentric amounts of the main shafts and the eccentric shafts of the shutter rotation shaft 61 and the plate rotation shaft 67 are the same. By rotating the plate member 66 supported in this manner eccentrically by the control motor M4, the respective shutter rotation shafts 61 are rotated synchronously, and the shutter pieces 62 of the respective shutter devices 6 are rotated. This plate member 66 rotates eccentrically below the plate member 57 so as not to interfere with the eccentric rotation of the plate member 57 that rotates the gear rotation shaft 54.

The shutter piece 62 of the shutter device 6 can be controlled to rotate continuously or intermittently at a required rotational speed. In the case of intermittent rotation, for example, the shutter is stopped at a position where the four shutter pieces 62 are arranged to form a substantially square shape, and the shutter opening 63 is opened to the maximum (FIG. 7A). )), Rotating at a required rotational speed set based on a command from the control device 8, the tips of the cutting blades 68 of the shutter pieces 62 are gathered at the center of the shutter opening 63 to close the shutter opening 63 (see FIG. 7 (B)), and further rotating each shutter piece 62 to widen a new shutter opening 63, each shutter piece 62 stops again at a position rotated 180 degrees from the standby position (FIG. 7C). Thus, one encapsulated food P can be divided from the rod-shaped food dough D continuously extruded from the polymerization nozzle device 5. And the shutter piece 62 divides | segments the next foodstuff P by the closing operation | movement of the cutting blade 69 by rotating 180 degree | times similarly to the said operation | movement. In this way, the shutter piece 62 continues to rotate in one direction, whereby the opening and closing of the shutter opening 63 is alternately repeated to produce a plurality of encapsulated foods P.

In the food production apparatus 1, a shutter piece 62 is disposed at a distance from the lower surface of the outer nozzle base 36 of the polymerization nozzle device 5, and the shutter piece 61 is fixed to the polymerization nozzle device 5 without moving up and down. . As described above, the standby time of the shutter piece 62 (or the ratio of the standby time in the rotation range of 180 degrees) is relatively long, and the rotation time of the shutter piece 62 (or rotation time in the rotation range of 180 degrees). The tip of the shutter piece 62 does not stop near the center of the shutter opening 63, and preferably passes through the center at the highest rotational speed of the shutter piece 62. Thus, by forming the new shutter opening 63, it is possible to divide the encapsulated food P without hindering the flow of the rod-shaped food dough D continuously extruded from the polymerization nozzle device 5.

The conveying device 7 uses a belt conveyor in which two conveying belts 71 are run in parallel, and is detachably attached to the main body frame 2 below each shutter device 6. In addition, the conveying device 7 includes a cradle 72 whose vertical position can be adjusted at a position corresponding to the lower side of the shutter device 7 inside the conveying belt 71, and the lower surface of the shutter piece 62 and the traveling surface of the conveying belt 71. The distance from the (upper surface) is settable. The transport belt 71 is continuously driven at a required transport speed by the control motor M5 or intermittently in response to the cutting operation of the shutter device 6, and the packaged food P divided by the shutter device 6 is transported downstream. Transport to.

Next, a food production apparatus 1 according to a second embodiment of the present invention will be described with reference to FIG. Although the shutter device 6 according to the first embodiment has been described with the configuration in which the shutter piece 62 including the two cutting blades 68 and the cutting blade 69 is rotated in one direction, the embodiment of the present invention is limited to this. It is not a thing. For example, in the shutter device 6 according to the second embodiment of the present invention, the shutter rotation shaft 61 does not rotate in one direction, but reciprocates (synonymous with rotation) within a required angle range. . That is, a swinging shutter is used. In addition, the same code | symbol is provided to what has the structure and function similar to the structure which concerns on 1st Embodiment, and the overlapping description is abbreviate | omitted.

The shutter device 6 includes six shutter rotation shafts 61 arranged at equal intervals on a circumference centered on the communication hole 23 of the drive box 22 in a plan view, and a shutter piece on a main shaft 61A of each shutter rotation shaft 61. 81 is detachably fixed. The shutter piece 81 has a required thickness, and two action surfaces 81A and 81B for covering and cutting the rod-shaped food dough D when the shutter opening 63 is closed are symmetrically arranged via the tip of the shutter piece 81. I have. The front end of the shutter piece 81 has a structure in contact with the action surface 81A of one adjacent shutter piece 81 and the action surface 81B of the other adjacent shutter piece 81.

Further, the control motor M4 for driving the shutter device 6 is controlled by the control device 8 so that its output shaft reciprocates within a range of a required angle, and the plate member 66 reciprocates by eccentric rotation so that the shutter rotation shaft 61 is rotated. Is reciprocated. The shutter piece 81 stops at a position (referred to as one reciprocating end) where the six shutter pieces 81 are arranged so as to form a substantially hexagon, and waits with the shutter opening 63 fully opened ( (See FIG. 8 (A)), rotating at a required rotational speed set based on a command from the control device 8 (synonymous with rocking), and the tips of the shutter pieces 81 are gathered at the center of the shutter opening 63 to form a shutter. The opening 63 is closed (see FIG. 8B), and each shutter piece 81 is rotated by a required angle from the standby position while continuing to rotate each shutter piece 81 to expand a new shutter opening 63 (the other reciprocation). It stops again (referred to as an end) (see FIG. 8C). One covered food P can be divided from the rod-shaped food dough D continuously extruded from the polymerization nozzle device 5 by the shutter piece 81 swinging in the forward path. Then, after the shutter piece 81 has stopped for a required time, the shutter piece 81 rotates in the opposite direction to the above operation and swings the return path to divide the next food to be encapsulated P. One of the pieces shown in FIG. Return to the round-trip end. That is, when the shutter piece 81 reciprocates once, the shutter opening 63 opens and closes twice to divide the two food products P from the rod-shaped food dough D. In this way, the shutter piece 81 repeats reciprocating rotation, whereby the opening and closing of the shutter opening 63 is alternately repeated to produce a plurality of encapsulated foods P.

As can be understood from the above description, when the food production device 1 removes the polymerization nozzle device 5 from the drive unit 21, the communication hole 23 of the drive box 22 has no unevenness such as a step. Easy to clean. Furthermore, since the drive box 22 can have a highly airtight structure, it can be washed with high-pressure water.

In addition, the superposition nozzle device 5 and the shutter device 6 are arranged concentrically in a plan view by the positioning means, and even if the superposition nozzle device 5 and the shutter device 6 are repeatedly attached to and detached from the drive box 22, they are not displaced. It is possible to install. Moreover, the superposition | polymerization nozzle apparatus 5, the shutter apparatus 6, and the drive part 21 are provided integrally, and can simplify a structure compared with the conventional foodstuff manufacturing apparatus.

The description of the food production apparatus 1 according to the embodiment of the present invention is generally as described above. However, the present invention is not limited to this, and various modifications can be made within the scope of the claims. For example, in the above description, the case where the encapsulated food P in which the second food D2 is included inside the first food D1 is manufactured has been described. However, only one of the food feeding devices is provided, and one type of food is used from the nozzle device. It may be a food manufacturing apparatus for discharging a stick-shaped food dough and dividing it into a required divided food by a shutter device. In addition, it may be a case of three or more kinds of ingredients, and moreover, not only a stick-shaped food coated with a plurality of ingredients concentrically, but also a food that produces a divided food from a stick-shaped food dough that is layered or laminated in a lattice shape It may be a manufacturing apparatus.

DESCRIPTION OF SYMBOLS 1 Food manufacturing apparatus 3 1st food supply apparatus 4 2nd food supply apparatus 5 Polymerization nozzle apparatus, nozzle apparatus 6 Shutter apparatus 7 Conveyance apparatus 8 Control apparatus 9 Conveyance apparatus, belt conveyor 21 Drive part 23 Communication hole 34 Rotating body 44 Rotating gear body 45 Holding portion 47 Base holder 48 Outer holder 53 Driving gear 54 Gear rotating shaft 61 Shutter rotating shaft 62 Shutter piece 81 Shutter piece D1 First food D2 Second food D Stick food dough P Covered food, divided food

Claims (5)

It has a nozzle device (5) for continuously extruding the rod-shaped food dough (D) and a plurality of shutter pieces (69, 81), and opens and closes a shutter opening (63) formed by surrounding the shutter pieces. A food production apparatus (1) comprising a shutter device (6) for dividing a divided dough (P) of a required size from a rod-shaped food dough (D),
A box-shaped drive box (22) equipped with a rotation drive mechanism of the shutter device (6) is provided with a communication hole (23) penetrating in the vertical direction through which the rod-shaped food dough (D) flows down,
The nozzle device (5) is inserted into the communication hole (23) from above to be fixed at a predetermined position, and is detachably attached to the upper surface of the drive box (22).
The nozzle device (5) includes a rotating body (34) rotating inside thereof.
Above the drive box (22), a drive gear (53) meshing with the rotating body (34) is detachably attached to the drive gear rotation shaft (54),
A plurality of shutter pieces (69, 81) of the shutter device (6) are arranged below the drive box (22) and connected to the rotation drive mechanism without moving up and down with respect to the drive box (22). The food manufacturing apparatus, wherein the shutter rotating shaft (61) is detachably provided. The food manufacturing apparatus according to claim 1,
The food manufacturing apparatus according to claim 1, wherein the drive box (22) includes a rotation drive mechanism for rotating the drive gear rotation shaft (54) therein. The food manufacturing apparatus according to claim 1,
The said shutter apparatus (6) is a rotary shutter provided with the shutter piece (62) rotatable in the same direction, Comprising: Opening and closing of shutter opening (63) are repeated alternately, The said foodstuff manufacturing apparatus characterized by the above-mentioned. The food manufacturing apparatus according to claim 1,
The shutter device (6) is an oscillating shutter having a reciprocatingly rotatable shutter piece (81), and the shutter piece (81) disposed at one reciprocating end rotates to open a shutter opening (63). Is moved from the open state to the closed state, and further, the shutter piece (81) is rotated in the same direction and the new shutter opening (63) is moved to the open state, and the other reciprocating end is arranged. The shutter piece (81) is rotated in the opposite direction to the forward path, and the return path returning to one reciprocating end is alternately rotated to alternately open and close the shutter opening (63). manufacturing device. The food manufacturing apparatus according to claim 2,
The rotation drive mechanism of the shutter device (6) and / or the rotation drive mechanism of the nozzle device (5) incorporated in the drive box (22) is a plate rotation having a main shaft and an eccentric shaft that is eccentric to the main shaft. The food manufacturing apparatus comprising: a shaft, wherein the main shaft is interlocked with a control motor, and a plate member is interlocked with the eccentric shaft to rotate the plate member eccentrically.