JP2012096925A - Device and method of delivering strained lees of food - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device for delivering strained lees of food which can reliably deliver the strained lees of food into a conveyance pipe by means of compression air and does not cause back flow of the strained lees of food and air.SOLUTION: The device for delivering the strained lees of food includes: a hopper 14 into which the strained lees 12 of food is thrown; and an extrusion pipe 16 which is located such that a side surface opening part 16a is communicated with the lower end opening part 14a of the hopper 14. The device includes a delivery cylinder 18 in which the tip end side of the extrusion pipe 16 is inserted obliquely to an internal space and the tip end part 16b of the extrusion pipe 16 is opened. The device includes an opening and closing valve 28 which is disposed at the tip end part 16b of the extrusion pipe 16, opens the tip end opening part 16c of the extrusion pipe 16 in the direction where the strained lees 12 of food is extruded from the extrusion pipe 16, and closes the tip end opening part 16c in an opposite direction. Further, the device has an extrusion screw 26 which is inserted into the extrusion pipe 16 of the part communicating with the hopper 14 and a driving motor 22 which rotates the extrusion screw 26. Therein, a pipe through which compression air flows is connected to opening parts in the front and rear parts of the delivery cylinder 18.

Description

  The present invention relates to a food squeeze feed device that feeds food squeezed residue such as okara discharged in a tofu production process to a conveyance pipe using air pressure.

  Conventionally, for example, okara, which is a food pomace that is discharged in the tofu manufacturing process, is discharged in large quantities, so the okara after squeezing the soy milk at the tofu manufacturing factory is put into the okara storage tank by a predetermined transport device. It is carried out and carried out as industrial waste. For example, a pressure feeding device using air pressure as disclosed in Patent Document 1 is used for the conveyance from the inside of the tofu manufacturing factory.

  The okara conveying device disclosed in Patent Document 1 has a rotary valve attached to the lower end of a hopper into which okara is charged, and a pipe to which compressed air is supplied is provided below the rotary valve. . Okara thrown into the hopper is sent into the pipe through a rotary valve and sent to the downstream okara storage section by airflow.

JP 2005-119854 A

  In the case of the conventional okara conveying device disclosed in Patent Document 1, if okara is clogged downstream of the rotary valve of the compressed air supply conduit, the compressed air is passed through the gap between the movable portion of the device and its side wall. There is a case where the karaoke squirts from the hopper and scatters around. Furthermore, since okara sent from the rotary valve falls into a lump in the air supply pipeline and is conveyed while being crushed by the air flow, if a large amount of okara is fed into the pipeline, In some cases, the okara clogged, and the okara backflowed through the rotary valve together with the compressed air and spouted into the hopper. In addition, rotary valves and other rotating bodies are always easily worn by rubbing against the side walls, etc., and when worn, the okara flows backward from the gap with compressed air and is easily ejected into and around the hopper. The replacement cycle was short and the durability was low.

  The present invention has been made in view of the above-mentioned background art, and is capable of reliably delivering food squeezed residue into a conveying pipe made of compressed air, and does not have food squeezed residue or air backflow. The purpose is to provide.

  The present invention relates to a hopper into which a food pomace is charged, an extruded tube in which a side surface opening communicates with a lower end opening of the hopper, and a distal end side of the extruded tube is inserted obliquely into an internal space. A feed tube having an open end, a backflow preventing portion for preventing food squeezed residue from being pushed out from the tip of the push tube and preventing a reverse flow from the feed tube side, and a portion communicating with the hopper inserted into the push tube Compressed air flows from the rear of the delivery cylinder to the front where the opening of the extrusion pipe is located, connected to the extrusion screw that has been made, the drive mechanism that rotates the extrusion screw, and the front and rear openings of the delivery cylinder It is a food pomace delivery device provided with piping.

  The extrusion tube is formed so that food pomace can be filled in a portion from the tip of the extrusion screw to the on-off valve. Furthermore, the said backflow prevention part is a front-end | tip part of the said extrusion pipe | tube with which the said food pomace was filled.

  A pomace disassembling member for decomposing the food pomace lump extruded from the opening is provided around the opening of the extruded tube.

  The backflow prevention unit is an on-off valve provided at a tip opening of the extrusion tube. The disc-shaped on-off valve of the extruded tube is provided so as to be movable in parallel at equal intervals with respect to the circular opening of the extruded tube.

  Around the opening of the extruded tube, there is provided a pomace decomposing member that decomposes the food pomace lump extruded from the opening, and the pomace decomposing member includes the opening of the extruding tube and the It is located between the on-off valve.

  Around the opening of the extrusion tube, the compressed air is squeezed into the food squeezed residue by narrowing a flow path of compressed air flowing through the delivery cylinder with respect to the food squeezed lump extruded from the opening. A device provided with a throttle member for spraying. The throttle member is a plurality of nozzles provided around the opening of the extruded tube. The plurality of nozzles are located above the extruded tube.

  The on-off valve of the push-out pipe is located at or below the center of the space in the delivery tube. Further, the on-off valve of the extruded tube is formed in a disk shape that closes the circular opening of the extruded tube, and is biased toward the inside of the extruded tube so as to close the opening. is there.

  The delivery tube is formed so that the cross-sectional area decreases from the distal end portion of the extruded tube toward the downstream side.

  The food squeeze waste delivery device of the present invention can efficiently send out the food squeeze residue to the food squeeze residue delivery pipe through which compressed air flows, and there is no backflow or blowout of compressed air due to clogging of the food squeeze residue. The residue does not spout from the food squeeze hopper. Therefore, the periphery of the food squeeze hopper can be kept clean at all times, and the environment of the food squeeze manufacturing factory can be improved to a cleaner one.

It is a side view which shows the food pomace sending apparatus of 1st embodiment of this invention. It is the side view which removed the funnel part of the food pomace sending device of a first embodiment of this invention. It is a partially broken side view of the food pomace delivery device of the first embodiment of this invention. It is a front view which shows the extrusion pipe front-end | tip part of the food pomace delivery apparatus of 1st embodiment of this invention. It is a fragmentary longitudinal cross-section which shows the food pomace delivery apparatus of 2nd embodiment of this invention. It is a front view which shows the extrusion pipe front-end | tip part of the food pomace delivery apparatus of 2nd embodiment of this invention. It is a perspective view of the extrusion pipe front-end | tip part of the food pomace delivery apparatus of 2nd embodiment of this invention. It is a perspective view of the food pomace delivery apparatus of 3rd embodiment of this invention.

  Hereinafter, the food pomace sending apparatus of 1st embodiment of this invention is demonstrated based on FIGS. 1-4. The food squeeze feed apparatus 10 of this embodiment includes an inverted square frustum-shaped hopper 14 into which a food squeezed meal 12 that is a squeezed soymilk squeezed from soybeans, and a lower end opening of the hopper 14. 14a is provided with an extrusion tube 16 in which a side opening 16a communicates, and a delivery tube 18 in which the distal end portion of the extrusion tube 16 is inserted obliquely into the internal space and the distal end portion of the extrusion tube 16 is opened. .

  In the hopper 14, an upper end opening 14 b is formed in a square with a large area, and a lower end opening 14 a having a small area communicates with and is connected to the extruded tube 16. The remaining food pomace 12 squeezed soymilk is put into the hollow internal space 14 c of the hopper 14.

  The side surface of the extruded tube 16 is connected to the lower end opening portion 14a of the hopper 14, and the peripheral edge portion of the side surface opening portion 16a of the extruded tube 16 and the peripheral edge portion of the lower end opening portion 14a of the hopper 14 are joined by welding or the like. The part is formed fluid-tight. A transmission 20 and a drive motor 22, which are drive mechanisms, are attached to the base end portion 16 a of the extrusion tube 16, and a drive shaft (not shown) of the drive motor 22 is provided in the extrusion tube 16 via a transmission gear of the transmission 20. It is connected to the screw rotating shaft 24. The screw rotation shaft 24 is supported by the base end portion 16a of the extrusion tube 16, and an extrusion screw 26 formed in a spiral shape around the screw rotation shaft 24 so as to be in contact with the inner wall surface of the extrusion tube 16 is predetermined. It is integrally provided with a length. The tip 24 a of the screw rotation shaft 24 extends to the vicinity of the tip 16 b of the extruded tube 16.

  The distal end side from the intermediate portion of the extrusion tube 16 is inserted and fixed obliquely inward from the side surface of the cylindrical delivery tube 18. Further, the distal end portion 16 b of the extruded tube 16 is positioned so as to be bent in a direction that is coaxial and parallel to the delivery tube 18.

  The distal end portion 16b of the extruded tube 16 has a disk-like shape that opens the distal end opening portion 16c of the extruded tube 16 in the protruding direction in which the food pomace 12 is pushed out of the extruded tube 16 and closes the distal end opening portion 16c in the opposite direction. The on-off valve 28 is provided so as to be fitted. The side peripheral surface of the on-off valve 28 and the inner surface of the opening edge of the tip opening 16c are formed as tapered surfaces that can come into surface contact with each other. A guide bolt 32 is inserted in the center of the on-off valve 28, and the tip end portion of the guide bolt 32 is fixed to a holding bar 30 fixed in the tip end portion 16b of the extruded tube 16 by welding or the like. A compression coil spring 34 is inserted and attached to the guide bolt 32 between the bolt head 32 a of the guide bolt 32 and the on-off valve 28. The on-off valve 28 is always urged by the compression coil spring 34 so as to be fitted toward the distal end opening 16c of the extruded tube 16, thereby closing the distal end opening 16c. As shown in FIG. 4, a guide rod 36 is inserted into the on-off valve 28 slightly away from the guide bolt 32, and the on-off valve 28 is provided so as to be movable with respect to the guide rod 36. The base end portion of the guide bar 36 is also fixed to the holding bar 30. As a result, the opening / closing valve 28 can be opened and closed along the guide bolt 32 with its peripheral edge moving in parallel at equal intervals with respect to the circular tip opening 16c of the extruded tube 16 without rotating. Yes.

  The delivery cylinder 18 is formed in a cylindrical shape with a large diameter at the center to which the hopper 14 is attached, and on both sides thereof, two-stage frustoconical funnels 40 and 42 are provided as shown in the figure. . The funnel portion 40 opposed to the distal end portion 16b of the extruded tube 16 is formed to have a diameter that is reduced in two steps from one end of the cylindrical portion 18a formed to have the same diameter as the large diameter portion of the delivery tube 18. A funnel-shaped small-diameter portion 40a is attached. A pipe 44 through which compressed air flows is connected to the small diameter side end of the small diameter part 40a of the funnel part 40. Similarly, the other end opening of the delivery cylinder 18 is provided with a funnel portion 42 whose diameter is reduced in two stages, and a pipe 46 through which compressed air is sent from a compressed air source is provided at the small diameter portion of the funnel portion 42. It is connected.

  Next, operation | movement and an effect | action of the food pomace sending apparatus 10 of one Embodiment of this invention are demonstrated. In the food squeeze sending device 10, the food squeezed scum 12 which is soybean soy milk squeezed used in the production of tofu is introduced into the hopper 14 from the upper end opening 14b from a conveying device (not shown). At the same time, the drive motor 22 is rotated to rotate the screw rotating shaft 24. The introduced food pomace 12 is fed into the extrusion tube 16 where the extrusion screw 26 is located via the side opening 16a. In the extrusion tube 16, the food pomace 12 is pushed out in the distal direction along the spiral of the extrusion screw 26 by the rotation of the extrusion screw 26. The food pomace 12 extruded by the extrusion screw 26 is pushed into the distal end portion 16 b of the extrusion tube 16.

  At the distal end portion 16 b of the extruded tube 16, the on-off valve 28 closes the on-off valve 28 with a constant pressing force by the compression coil spring 34, and the pushing force of the food pomace 12 exceeds the pressing force of the compression coil spring 34. The on-off valve 28 does not open until power is applied. Thereby, the food pomace that has entered the extrusion tube 16 is reliably pushed by the extrusion screw 26 in the direction of the tip portion 16b, and the tip portion 16b is filled with the food pomace 12 densely.

  In this state, even if the supply amount of the food squeeze residue 12 is reduced or the extrusion screw 26 is stopped, the food squeeze residue 12 clogged in the end portion 16b of the open / close valve 28 and the extrusion tube 16 causes the pipe 44 side. Compressed air does not flow backward. Therefore, the front end portion 16b of the extruded tube 16 filled with the food pomace 12 also functions as a backflow prevention portion.

  When the food pomace 12 is further pushed out by the extrusion screw 26 and the pushing force of the food pomace 12 exceeds the urging force of the on-off valve 28, the on-off valve 28 is brought into the elastic force of the compression coil spring 34 by the pushing force. It moves against the guide bolt 32 in the opening direction, and the food pomace 12 in the distal end portion 16b of the extruded tube 16 is pushed out from the distal end opening portion 16c to the side. Since the compressed air flows in the delivery cylinder 18 and the flow velocity is accelerated by the funnel portion 40 of the delivery cylinder 18, the food pomace 12 extruded around the tip opening 16 c of the extrusion pipe 16 is caused by wind pressure. It is blown off into the funnel 40 of the delivery tube 18, moves in the pipe 44 by riding on the air flow, and is put into a predetermined food pomace storage tank. In this way, the food pomace 12 is continuously fed into the pipe 44 and reliably conveyed by the air flow.

  The food squeezed residue sending device 10 of this embodiment can efficiently send out the food squeezed residue 12 to the pipe 44 through which the compressed air flows, and there is no backflow of compressed air and no blowout of the food squeezed residue 12 from the hopper 14. . In particular, the food pomace 12 clogged in the tip end portion 16b of the extrusion tube 16 even when the extrusion screw 26 is stopped with the open / close valve 28 opened in the state where the tip opening portion 16c of the extrusion tube 16 is clogged. Thus, the reverse flow of the compressed air flow is prevented, and the compressed air and the food pomace 12 do not spout from the hopper 14. Further, when the amount of the food squeezed residue 12 is small, the on-off valve 28 is maintained in a closed state, and the food squeeze residue 12 and the backflow of the compressed air are prevented.

  Next, the food pomace sending device according to the second embodiment of the present invention will be described with reference to FIGS. Here, the same members as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted. The food pomace delivery device 50 of this embodiment is also a device for air-conveying the food pomace 12 such as a pomace obtained by squeezing soy milk from soybeans or a pomace obtained by squeezing beer. The overall structure of the food pomace sending device 50 is the same as that of the above embodiment, and the structures of the sending tube 18 and the tip portion 16b of the extruded tube 16 inserted therein are different.

  Also in the delivery cylinder 18 of the food pomace delivery device 50, a funnel portion 52 having a diameter that is narrowed in two stages is provided in the one end opening 18b. A pipe 44 through which compressed air is sent is connected to the tip of the small diameter portion of the funnel portion 52. The distal end portion 16b of the extruded tube 16 is located in the funnel portion 52 of the delivery cylinder 18, and a throttle wall 54 as a throttle member for restricting the flow path of the compressed air flowing in the delivery cylinder 18 is provided in the one end opening 18b. , Provided perpendicular to the air flow direction of the delivery cylinder 18. The diaphragm wall 54 is formed as a diaphragm 54a by opening about 1/3 below the one end opening 18b. The restricting portion 54 a opens below the distal end portion 16 b of the extruded tube 16 and restricts the flow path of the delivery cylinder 18. Further, a plurality of nozzles 56 provided around the upper end opening 16c of the extruded tube 16 are provided on the throttle wall 54 located above the distal end portion 16b of the extruded tube 16 so as to project in the flow path direction. Yes. Furthermore, a guide plate 58 that guides the air flow of the throttle portion 54 in the downstream direction extends in the flow path direction at the end of the throttle wall 54 on the throttle portion 54a side. As shown in FIG. 5, the funnel portion 52 has an inner diameter that becomes narrower toward the downstream side of the air flow, and is formed in a shape in which the center of the cross-sectional circle is eccentric downward.

  A pomace disassembling member 60 for disassembling the lump of the food pomace 12 extruded from the front end opening 16c to the peripheral portion is provided around the front end opening 16c of the extruded tube 16. The squeezed fall members 60 are fixed at equal intervals around the distal end opening 16 c of the extruded tube 16 and protrude parallel to each other in the moving direction of the on-off valve 28. Therefore, the on-off valve 28 is provided so as to be movable in parallel so as to be in contact with the inside of the squeezed disassembly member 60.

  The food pomace delivery device 50 of this embodiment has a pomace disassembly member 60 around the extrusion tube 16 in the delivery cylinder 18 and a compressed portion 54a for accelerating the flow of compressed air around it. Since the nozzle 56 for injecting the air is disposed, the lump of the food pomace 12 from which the distal end opening portion 16c of the extrusion tube 16 is extruded is easily finely crushed and rides in the flow of compressed air in the funnel portion 52. The finely squeezed food waste 12 that has moved and is finely conveyed is preferably conveyed by the pipe 44.

  Next, the food pomace sending device according to the third embodiment of the present invention will be described with reference to FIG. Here, the same members as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted. The food pomace sending device 62 of this embodiment is also a device for air-conveying the food pomace 12 such as a pomace obtained by squeezing soy milk from soybeans or a pomace obtained by squeezing beer. The overall structure of the food pomace feeding device 62 is the same as that of the above embodiment, and a pair of delivery cylinders 18 and a pair of extrusion tubes 16 inserted therein are provided on the lower end side of the horizontally long hopper 14. It is a thing.

  The food squeezed residue sending device 62 of this embodiment also has the same effect as the above embodiment, and is suitable for transporting a larger amount of the food squeezed residue 12.

  The food squeeze meal delivery device of the present invention is not limited to the above embodiment, and when pressure is applied so that the open / close valve 28 is urged toward the tip opening 16c of the extruded tube 16 by the atmospheric pressure in the delivery cylinder 18. The compression coil spring 34 may not be provided. Furthermore, the position of the distal end portion 16b of the extruded tube 16 may be disposed at an eccentric lower position in addition to the central portion of the delivery tube 18. Thereby, the space below the tip portion 16b is narrowed, the speed of the air flow is increased, and the food pomace that tends to fall downward is reliably conveyed by the high-speed air flow.

  In addition, the structure of the on-off valve, the drive mechanism, the size and shape of the extrusion screw can be set as appropriate, and the size and length of the extrusion tube and delivery tube can also be set as appropriate.

10, 50, 62 Food squeeze residue delivery device 12 Food squeeze residue 14 Hopper 14a Lower end opening 14b Upper end opening 16 Extrusion tube 16a Base end 16b Tip end 16c End opening 18 Delivery cylinder 22 Drive motor 24 Screw rotating shaft 26 Extrusion Screw 28 On-off valve 32 Guide bolt 34 Compression coil springs 40, 42, 52 Roto portions 44, 46 Piping

The present invention relates to a food squeeze waste delivery device and a food squeeze waste delivery method for delivering food squeezed residue such as okara discharged in a tofu production process to a conveyance line using air pressure.

  Conventionally, for example, okara, which is a food pomace that is discharged in the tofu manufacturing process, is discharged in large quantities, so the okara after squeezing the soy milk at the tofu manufacturing factory is put into the okara storage tank by a predetermined transport device. It is carried out and carried out as industrial waste. For example, a pressure feeding device using air pressure as disclosed in Patent Document 1 is used for the conveyance from the inside of the tofu manufacturing factory.

  The okara conveying device disclosed in Patent Document 1 has a rotary valve attached to the lower end of a hopper into which okara is charged, and a pipe to which compressed air is supplied is provided below the rotary valve. . Okara thrown into the hopper is sent into the pipe through a rotary valve and sent to the downstream okara storage section by airflow.

JP 2005-119854 A

  In the case of the conventional okara conveying device disclosed in Patent Document 1, if okara is clogged downstream of the rotary valve of the compressed air supply conduit, the compressed air is passed through the gap between the movable portion of the device and its side wall. There is a case where the karaoke squirts from the hopper and scatters around. Furthermore, since okara sent from the rotary valve falls into a lump in the air supply pipeline and is conveyed while being crushed by the air flow, if a large amount of okara is fed into the pipeline, In some cases, the okara clogged, and the okara backflowed through the rotary valve together with the compressed air and spouted into the hopper. In addition, rotary valves and other rotating bodies are always easily worn by rubbing against the side walls, etc., and when worn, the okara flows backward from the gap with compressed air and is easily ejected into and around the hopper. The replacement cycle was short and the durability was low.

The present invention has been made in view of the above-mentioned background art, and is capable of reliably delivering food squeezed residue into a conveying pipe made of compressed air, and does not have food squeezed residue or air backflow. The object is to provide a food pomace delivery method .

The present invention includes a hopper into which a food pomace is charged, an extruded tube in which a side opening communicates with a lower end opening of the hopper, a distal end of the extruded tube is inserted into an internal space, and a distal end of the extruded tube A delivery cylinder having an opening, an extrusion screw inserted into the extrusion tube at a portion communicating with the hopper, a drive mechanism for rotating the extrusion screw, and an opening portion at the front and rear of the delivery cylinder. It is a food pomace sending device provided with the piping in which an air flow is formed toward the front where the opening of the extrusion pipe was located from the back.

The distal end portion of the extrusion tube is provided with a backflow prevention portion that pushes out the food pomace and prevents backflow from the delivery tube side, and the extrusion tube is provided with a portion of food from the distal end of the extrusion screw to the on-off valve. A pomace is formed so that filling is possible. The said backflow prevention part is good in it being the structure where the front- end | tip part of the said extrusion pipe | tube filled with the said food pomace is shared . The backflow prevention unit may be an on-off valve provided at a tip opening of the extrusion tube.

Further, the present invention provides a hopper into which food pomace is charged, an extruded tube in which a side opening is communicated with a lower end opening of the hopper, and a distal end of the extruded tube is inserted into an internal space and the distal end of the extruded tube A delivery cylinder having a portion opened, and a pipe connected to the front and rear openings of the delivery cylinder to form an air flow from the rear of the delivery cylinder toward the front where the opening of the extrusion tube is located, This is a food pomace feeding method in which an air flow is caused to flow through the delivery pipe, and the food squeezed rice cake extruded from the tip of the extrusion pipe is crushed by the air flow and conveyed in the pipe.

The food pomace delivery device and the food pomace delivery method according to the present invention can efficiently send out the food pomace to the food pomace conveyance pipe through which the pressurized compressed air flows and compress the food pomace by clogging. There is no air backflow and no blowout, and the food pomace does not spout from the food hopper input hopper. Therefore, the periphery of the food squeeze hopper can be kept clean at all times, and the environment of the food squeeze manufacturing factory can be improved to a cleaner one.

It is a side view which shows the food pomace sending apparatus of 1st embodiment of this invention. It is the side view which removed the funnel part of the food pomace sending device of a first embodiment of this invention. It is a partially broken side view of the food pomace delivery device of the first embodiment of this invention. It is a front view which shows the extrusion pipe front-end | tip part of the food pomace delivery apparatus of 1st embodiment of this invention. It is a fragmentary longitudinal cross-section which shows the food pomace delivery apparatus of 2nd embodiment of this invention. It is a front view which shows the extrusion pipe front-end | tip part of the food pomace delivery apparatus of 2nd embodiment of this invention. It is a perspective view of the extrusion pipe front-end | tip part of the food pomace delivery apparatus of 2nd embodiment of this invention. It is a perspective view of the food pomace delivery apparatus of 3rd embodiment of this invention.

  Hereinafter, the food pomace sending apparatus of 1st embodiment of this invention is demonstrated based on FIGS. 1-4. The food squeeze feed apparatus 10 of this embodiment includes an inverted square frustum-shaped hopper 14 into which a food squeezed meal 12 that is a squeezed soymilk squeezed from soybeans, and a lower end opening of the hopper 14. 14a is provided with an extrusion tube 16 in which a side opening 16a communicates, and a delivery tube 18 in which the distal end portion of the extrusion tube 16 is inserted obliquely into the internal space and the distal end portion of the extrusion tube 16 is opened. .

  In the hopper 14, an upper end opening 14 b is formed in a square with a large area, and a lower end opening 14 a having a small area communicates with and is connected to the extruded tube 16. The remaining food pomace 12 squeezed soymilk is put into the hollow internal space 14 c of the hopper 14.

  The side surface of the extruded tube 16 is connected to the lower end opening portion 14a of the hopper 14, and the peripheral edge portion of the side surface opening portion 16a of the extruded tube 16 and the peripheral edge portion of the lower end opening portion 14a of the hopper 14 are joined by welding or the like. The part is formed fluid-tight. A transmission 20 and a drive motor 22, which are drive mechanisms, are attached to the base end portion 16 a of the extrusion tube 16, and a drive shaft (not shown) of the drive motor 22 is provided in the extrusion tube 16 via a transmission gear of the transmission 20. It is connected to the screw rotating shaft 24. The screw rotation shaft 24 is supported by the base end portion 16a of the extrusion tube 16, and an extrusion screw 26 formed in a spiral shape around the screw rotation shaft 24 so as to be in contact with the inner wall surface of the extrusion tube 16 is predetermined. It is integrally provided with a length. The tip 24 a of the screw rotation shaft 24 extends to the vicinity of the tip 16 b of the extruded tube 16.

  The distal end side from the intermediate portion of the extrusion tube 16 is inserted and fixed obliquely inward from the side surface of the cylindrical delivery tube 18. Further, the distal end portion 16 b of the extruded tube 16 is positioned so as to be bent in a direction that is coaxial and parallel to the delivery tube 18.

  The distal end portion 16b of the extruded tube 16 has a disk-like shape that opens the distal end opening portion 16c of the extruded tube 16 in the protruding direction in which the food pomace 12 is pushed out of the extruded tube 16 and closes the distal end opening portion 16c in the opposite direction. The on-off valve 28 is provided so as to be fitted. The side peripheral surface of the on-off valve 28 and the inner surface of the opening edge of the tip opening 16c are formed as tapered surfaces that can come into surface contact with each other. A guide bolt 32 is inserted in the center of the on-off valve 28, and the tip end portion of the guide bolt 32 is fixed to a holding bar 30 fixed in the tip end portion 16b of the extruded tube 16 by welding or the like. A compression coil spring 34 is inserted and attached to the guide bolt 32 between the bolt head 32 a of the guide bolt 32 and the on-off valve 28. The on-off valve 28 is always urged by the compression coil spring 34 so as to be fitted toward the distal end opening 16c of the extruded tube 16, thereby closing the distal end opening 16c. As shown in FIG. 4, a guide rod 36 is inserted into the on-off valve 28 slightly away from the guide bolt 32, and the on-off valve 28 is provided so as to be movable with respect to the guide rod 36. The base end portion of the guide bar 36 is also fixed to the holding bar 30. As a result, the opening / closing valve 28 can be opened and closed along the guide bolt 32 with its peripheral edge moving in parallel at equal intervals with respect to the circular tip opening 16c of the extruded tube 16 without rotating. Yes.

  The delivery cylinder 18 is formed in a cylindrical shape with a large diameter at the center to which the hopper 14 is attached, and on both sides thereof, two-stage frustoconical funnels 40 and 42 are provided as shown in the figure. . The funnel portion 40 opposed to the distal end portion 16b of the extruded tube 16 is formed to have a diameter that is reduced in two steps from one end of the cylindrical portion 18a formed to have the same diameter as the large diameter portion of the delivery tube 18. A funnel-shaped small-diameter portion 40a is attached. A pipe 44 through which compressed air flows is connected to the small diameter side end of the small diameter part 40a of the funnel part 40. Similarly, the other end opening of the delivery cylinder 18 is provided with a funnel portion 42 whose diameter is reduced in two stages, and a pipe 46 through which compressed air is sent from a compressed air source is provided at the small diameter portion of the funnel portion 42. It is connected.

  Next, operation | movement and an effect | action of the food pomace sending apparatus 10 of one Embodiment of this invention are demonstrated. In the food squeeze sending device 10, the food squeezed scum 12 which is soybean soy milk squeezed used in the production of tofu is introduced into the hopper 14 from the upper end opening 14b from a conveying device (not shown). At the same time, the drive motor 22 is rotated to rotate the screw rotating shaft 24. The introduced food pomace 12 is fed into the extrusion tube 16 where the extrusion screw 26 is located via the side opening 16a. In the extrusion tube 16, the food pomace 12 is pushed out in the distal direction along the spiral of the extrusion screw 26 by the rotation of the extrusion screw 26. The food pomace 12 extruded by the extrusion screw 26 is pushed into the distal end portion 16 b of the extrusion tube 16.

  At the distal end portion 16 b of the extruded tube 16, the on-off valve 28 closes the on-off valve 28 with a constant pressing force by the compression coil spring 34, and the pushing force of the food pomace 12 exceeds the pressing force of the compression coil spring 34. The on-off valve 28 does not open until power is applied. Thereby, the food pomace that has entered the extrusion tube 16 is reliably pushed by the extrusion screw 26 in the direction of the tip portion 16b, and the tip portion 16b is filled with the food pomace 12 densely.

  In this state, even if the supply amount of the food squeeze residue 12 is reduced or the extrusion screw 26 is stopped, the food squeeze residue 12 clogged in the end portion 16b of the open / close valve 28 and the extrusion tube 16 causes the pipe 44 side. Compressed air does not flow backward. Therefore, the front end portion 16b of the extruded tube 16 filled with the food pomace 12 also functions as a backflow prevention portion.

  When the food pomace 12 is further pushed out by the extrusion screw 26 and the pushing force of the food pomace 12 exceeds the urging force of the on-off valve 28, the on-off valve 28 is brought into the elastic force of the compression coil spring 34 by the pushing force. It moves against the guide bolt 32 in the opening direction, and the food pomace 12 in the distal end portion 16b of the extruded tube 16 is pushed out from the distal end opening portion 16c to the side. Since the compressed air flows in the delivery cylinder 18 and the flow velocity is accelerated by the funnel portion 40 of the delivery cylinder 18, the food pomace 12 extruded around the tip opening 16 c of the extrusion pipe 16 is caused by wind pressure. It is blown off into the funnel 40 of the delivery tube 18, moves in the pipe 44 by riding on the air flow, and is put into a predetermined food pomace storage tank. In this way, the food pomace 12 is continuously fed into the pipe 44 and reliably conveyed by the air flow.

  The food squeezed residue sending device 10 of this embodiment can efficiently send out the food squeezed residue 12 to the pipe 44 through which the compressed air flows, and there is no backflow of compressed air and no blowout of the food squeezed residue 12 from the hopper 14. . In particular, the food pomace 12 clogged in the tip end portion 16b of the extrusion tube 16 even when the extrusion screw 26 is stopped with the open / close valve 28 opened in the state where the tip opening portion 16c of the extrusion tube 16 is clogged. Thus, the reverse flow of the compressed air flow is prevented, and the compressed air and the food pomace 12 do not spout from the hopper 14. Further, when the amount of the food squeezed residue 12 is small, the on-off valve 28 is maintained in a closed state, and the food squeeze residue 12 and the backflow of the compressed air are prevented.

  Next, the food pomace sending device according to the second embodiment of the present invention will be described with reference to FIGS. Here, the same members as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted. The food pomace delivery device 50 of this embodiment is also a device for air-conveying the food pomace 12 such as a pomace obtained by squeezing soy milk from soybeans or a pomace obtained by squeezing beer. The overall structure of the food pomace sending device 50 is the same as that of the above embodiment, and the structures of the sending tube 18 and the tip portion 16b of the extruded tube 16 inserted therein are different.

  Also in the delivery cylinder 18 of the food pomace delivery device 50, a funnel portion 52 having a diameter that is narrowed in two stages is provided in the one end opening 18b. A pipe 44 through which compressed air is sent is connected to the tip of the small diameter portion of the funnel portion 52. The distal end portion 16b of the extruded tube 16 is located in the funnel portion 52 of the delivery cylinder 18, and a throttle wall 54 as a throttle member for restricting the flow path of the compressed air flowing in the delivery cylinder 18 is provided in the one end opening 18b. , Provided perpendicular to the air flow direction of the delivery cylinder 18. The diaphragm wall 54 is formed as a diaphragm 54a by opening about 1/3 below the one end opening 18b. The restricting portion 54 a opens below the distal end portion 16 b of the extruded tube 16 and restricts the flow path of the delivery cylinder 18. Further, a plurality of nozzles 56 provided around the upper end opening 16c of the extruded tube 16 are provided on the throttle wall 54 located above the distal end portion 16b of the extruded tube 16 so as to project in the flow path direction. Yes. Furthermore, a guide plate 58 that guides the air flow of the throttle portion 54 in the downstream direction extends in the flow path direction at the end of the throttle wall 54 on the throttle portion 54a side. As shown in FIG. 5, the funnel portion 52 has an inner diameter that becomes narrower toward the downstream side of the air flow, and is formed in a shape in which the center of the cross-sectional circle is eccentric downward.

  A pomace disassembling member 60 for disassembling the lump of the food pomace 12 extruded from the front end opening 16c to the peripheral portion is provided around the front end opening 16c of the extruded tube 16. The squeezed fall members 60 are fixed at equal intervals around the distal end opening 16 c of the extruded tube 16 and protrude parallel to each other in the moving direction of the on-off valve 28. Therefore, the on-off valve 28 is provided so as to be movable in parallel so as to be in contact with the inside of the squeezed disassembly member 60.

  The food pomace delivery device 50 of this embodiment has a pomace disassembly member 60 around the extrusion tube 16 in the delivery cylinder 18 and a compressed portion 54a for accelerating the flow of compressed air around it. Since the nozzle 56 for injecting the air is disposed, the lump of the food pomace 12 from which the distal end opening portion 16c of the extrusion tube 16 is extruded is easily finely crushed and rides in the flow of compressed air in the funnel portion 52. The finely squeezed food waste 12 that has moved and is finely conveyed is preferably conveyed by the pipe 44.

  Next, the food pomace sending device according to the third embodiment of the present invention will be described with reference to FIG. Here, the same members as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted. The food pomace sending device 62 of this embodiment is also a device for air-conveying the food pomace 12 such as a pomace obtained by squeezing soy milk from soybeans or a pomace obtained by squeezing beer. The overall structure of the food pomace feeding device 62 is the same as that of the above embodiment, and a pair of delivery cylinders 18 and a pair of extrusion tubes 16 inserted therein are provided on the lower end side of the horizontally long hopper 14. It is a thing.

  The food squeezed residue sending device 62 of this embodiment also has the same effect as the above embodiment, and is suitable for transporting a larger amount of the food squeezed residue 12.

  The food squeeze meal delivery device of the present invention is not limited to the above embodiment, and when pressure is applied so that the open / close valve 28 is urged toward the tip opening 16c of the extruded tube 16 by the atmospheric pressure in the delivery cylinder 18. The compression coil spring 34 may not be provided. Furthermore, the position of the distal end portion 16b of the extruded tube 16 may be disposed at an eccentric lower position in addition to the central portion of the delivery tube 18. Thereby, the space below the tip portion 16b is narrowed, the speed of the air flow is increased, and the food pomace that tends to fall downward is reliably conveyed by the high-speed air flow.

  In addition, the structure of the on-off valve, the drive mechanism, the size and shape of the extrusion screw can be set as appropriate, and the size and length of the extrusion tube and delivery tube can also be set as appropriate.

10, 50, 62 Food squeeze residue delivery device 12 Food squeeze residue 14 Hopper 14a Lower end opening 14b Upper end opening 16 Extrusion tube 16a Base end 16b Tip end 16c End opening 18 Delivery cylinder 22 Drive motor 24 Screw rotating shaft 26 Extrusion Screw 28 On-off valve 32 Guide bolt 34 Compression coil springs 40, 42, 52 Roto portions 44, 46 Piping

Claims (13)

  A hopper into which food pomace is charged, an extruded tube whose side opening communicates with the lower end opening of the hopper, and a distal end of the extruded tube is inserted obliquely into the internal space, and the distal end of the extruded tube is opened. A feed tube, a backflow preventing portion for preventing food squeezed from the tip of the extrusion tube and preventing a backflow from the delivery tube side, and an extrusion screw inserted into the extrusion tube at a portion communicating with the hopper And a drive mechanism for rotating the extrusion screw, and a pipe connected to the front and rear openings of the delivery tube and through which compressed air flows from the rear of the delivery tube toward the front where the opening of the extrusion tube is located. A food pomace delivery device characterized by that.   The food squeeze waste feeding device according to claim 1, wherein the extrusion pipe is formed so that food squeeze scum can be filled in a portion from a tip of the extrusion screw to the on-off valve.   The food squeeze waste feeding device according to claim 2, wherein the backflow prevention part is a tip of the extrusion tube filled with the food squeeze dust.   The food squeeze debris delivery device according to claim 1, wherein a pomace debris disassembling member for decomposing the food pomace lump extruded from the opening is provided around the opening of the extrusion tube.   The food pomace feeding device according to claim 1, wherein the backflow prevention unit is an on-off valve provided at a tip opening of the extrusion tube.   6. The food squeeze waste feeding device according to claim 5, wherein the disk-shaped on-off valve of the extruded tube is provided so as to be movable in parallel at equal intervals with respect to the circular opening of the extruded tube.   Around the opening of the extruded tube, there is provided a pomace decomposing member that decomposes the food pomace lump extruded from the opening, and the pomace decomposing member includes the opening of the extruding tube and the The food squeeze waste delivery device according to claim 5, which is located between the on-off valve.   Around the opening of the extrusion tube, the compressed air is squeezed into the food squeezed residue by narrowing a flow path of compressed air flowing through the delivery cylinder with respect to the food squeezed lump extruded from the opening. 5. The food squeeze waste feeding device according to claim 1 or 4, wherein a squeezing member for spraying the food is provided.   The food squeeze feed apparatus according to claim 8, wherein the squeezing member is a plurality of nozzles provided around the opening of the extruded tube.   The food pomace feeding device according to claim 9, wherein the plurality of nozzles are positioned above the extrusion tube.   The food squeeze waste delivery device according to claim 5, wherein the on-off valve of the extrusion tube is located at or below the center of the space in the delivery cylinder. 6. The on-off valve of the extrusion tube is formed in a disk shape that closes a circular opening of the extrusion tube, and is biased toward the inside of the extrusion tube so as to close the opening. Food pomace delivery device. The food pomace feeding apparatus according to claim 1, wherein the feeding cylinder is formed so that a cross-sectional area decreases from a distal end portion of the extruded tube toward a downstream side.

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