RU1438144C - Device for filling of tins with fishes - Google Patents

Abstract

FIELD: fish industry. SUBSTANCE: device has coupled fish supply 1 with vibration motor, rotating table 2 with measuring cups 3 and pistons 4, disk knife 5, device for movement, centering and keeping the tins during putting fishes into them and tilter 6. Vibration motor of fish supply 1 includes plate 9 hinged fixed on bed, connecting rod 10 and rotating eccentric 11. Fish supply is provided with flange 14 interacting with stationary stop 15, fixed on bed. Plate 9 has on end a hole 16 for passing through it the connecting rod 10 which is provided to with flange 17 influencing on plate 9 during movement of connecting rod 10 upward. Device for movement, centering and keeping the tins is made in the form of multiple-thread screw 30, pair of curvilinear guides 31 and 32. Screw 30 is positioned over table 2 parallel with its plane, guides 31 and 32 are placed between screw 30 and table 2 forming canal for passing the pins. Tilter 6 is carried out in the form of driven drum mounted coaxially with screw 30 and provided with radial located clamps 34 for tins. EFFECT: improved efficiency, simplification of construction and compactness. 4 dwg

Description

 The invention relates to the fishing industry, and in particular to devices for packing fish or its pieces in cans in the production of canned goods and preserves at coastal fish processing enterprises and fishing vessels.

 The purpose of the invention is improving productivity, simplifying the design and compactness of the device.

 This is achieved as a result of the fact that the design of the vibrodrive of the fish farmer provides a dynamic effect on the tourniquet of the fish when filling the dosing cups, which allows to increase the speed of movement of the tourniquet and increase its density, and the design of the device for moving, centering and holding the cans when transferring the fish into them allows you to combine several operations, to greatly simplify the design of the device and increase its productivity, while the fish is laid at the same time in several cans.

 Figure 1 shows the kinematic diagram of a device for filling cans with fish; figure 2 is a diagram explaining the operation of the vibrator; figure 3 is a diagram of the path and speed of the farmer in the angle of rotation of the eccentric; figure 4 is a plan view of a device for moving, centering and holding cans when transferring fish to them.

 A device for filling cans with fish or its pieces contains a paired fish farmer 1 with a vibrodrive, a rotary table 2 with dosing cups 3 and pistons 4, a drive circular knife 5, a device for moving, centering and holding cans when transferring fish to them, tilter 6, estrus 7 for supplying empty cans and estrus 8 for removal of filled cans.

 The fish farmer 1 is driven in a reciprocating motion in a vertical plane by means of a vibrodrive, which includes a plate 9 pivotally mounted on the bed, to which the fish farmer 1 is suspended, a connecting rod 10, a rotating cam 11, a belt drive 12 with a speed variator and an electric motor 13. The fish farmer 1 is equipped a flange 14 interacting with a fixed stop 15 mounted on a bed. The plate 9 has an end 16 at the end for passage of the connecting rod 10 through it, which is equipped with a flange 17, a spring 18 and a nut 19. Table 2 with eight metering cups 3 makes intermittent (with outstands) rotational movement from the mechanism 20 of periodic rotation. Pistons 4 with rollers are mounted in metering cups 3 with the possibility of moving along them with an end fist 21, making a circular oscillatory motion relative to axis 22 by means of an eccentric mechanism 23. The disk knife 5 is mounted on the shaft 24, which receives rotation from the electric motor 25 through the belt 26 and gear 27 gears. The shaft 24 of the disk knife 5 makes a circular motion in the horizontal plane with the help of a carrier 28 and a chain gear 29. A device for moving the centering and holding the cans when shifting the fish into them consists of a two-way screw 30 and a pair of curved guides 31 and 32. The two-way screw 30 is mounted on the shaft 33 above the table 2 parallel to its plane and is driven into rotation. Curved guides 31 and 32 are fixedly mounted between table 2 and auger 30 and have a straight section in the entry area of empty cans, a curved section located on the periphery of table 2 and a straight section in the zone of transfer of filled cans to the tilter 6. Thus, the guides 31 and 32 form a channel for passage of cans in the "bottom up" position. The tilter 6 for turning the cans into the bottom-down position is made in the form of a cylindrical drum with radially spaced cans 34 for the cans. The tilter 6 is mounted coaxially to the screw 30 at its output end and rotates on its shaft 33, as on an axis using carrier 35 and gear system 36-39. The diameter of the tilting drum 6 is preferably equal to the diameter of the inner cylinder of the screw 30 to ensure unhindered passage of the cans from the channel formed by the guides 31 and 32 and the surface of the inner cylinder of the screw 30 to the grabs 31 of the tilting drum 6. The shell 40 holds the cans filled with fish during their flipping from position bottom up to bottom down.

 The device operates as follows.

The carcass cut into the carcass is loaded into fish farmer 1, where, under the influence of vertical vibration, a tourniquet of fish is formed, moving down. The vibrodrive design used in the device allows to increase the speed of movement of the bundle and its density, i.e. as a result, machine productivity and the stability of the dose of fish placed in cans are increased. The principle of operation of the vibrodrive is illustrated in figure 2 (where a, b, c, d are the positions of the elements of the vibrodrive at different positions of the eccentric 11 every 90 ^about its rotation).

When the position of the clown 11 in the top dead center (Fig. 2A), the fish farmer 1 is in its highest position. When turning the eccentric 11, the fish farmer 1 begins to lower, and the spring 18, resting on the nut 19 and the plate 9, provides the latter to be pressed to the connecting rod flange 17. After 90 ^° (π / 2) of the rotation angle of the eccentric 11 (Fig. 2b), the fish farmer 1 flange 14 hits a fixed stop 15 mounted on a bed. As can be seen from the diagram (Fig. 3), the speed of the fish-harness-fish system at this moment reaches its maximum value. Fisherman 1 instantly stops, and the fish harness rushes down under the dynamic impact. The difference in the speeds of fish farmer 1 and harness at this moment is maximum, i.e. the friction force between the fish and the walls of the farmer is minimal and does not interfere with the movement of the harness. With a further turn of the eccentric 11, the fish farmer 1 is stationary, and the connecting rod 10 goes down. In this case, the flange 17 is detached from the plate 9, and the nut 19 compresses the spring 18. The position of the system in the bottom dead center of the eccentric 11 (Fig. 2B). Between 180 and 270 ^about (π / 2 and 3 / 2π) of the rotation angle of the eccentric 11, the fish farmer 1 remains motionless, and the connecting rod 10 accelerates after passing the bottom dead center and again reaches its maximum speed to 270 ^about (3 / 2π) of the rotation angle of the eccentric 11 ( figure 3). At this moment (Fig. 2d), the connecting rod 10 with its flange 17 hits the end of the plate 9 and sharply raises the fish farmer 1 up. The speed of fish farmer 1 instantly increases from zero to the maximum value, while the speed of the fish harness is in the opposite direction at that time. Thus, the maximum difference in the speeds of the farmer and the fish harness is achieved, i.e., the braking of the harness is minimized by friction. The spring 18 at this time presses the end of the plate 9 against the flange 17 of the connecting rod 10. Next, the eccentric 11 comes to the top dead center, and the cycle repeats. A tourniquet of fish leaving the farmer 1 fills the metering glasses 3 in pairs. At this time, the pistons 4 are in the lower position. Then the circular knife 5 cuts the tourniquet, after which table 2 with glasses 3 and fist 21 simultaneously rotate 90 ^about . At the same time, glasses 3 filled with fish are removed from under the fish farmer 1 to an intermediate position. Glasses 3, filled with fish and located in an intermediate position at the previous moment, are moved to the position where the fish are transferred to jars. Empty cans from estrus 7 enter a straight section of guides 31 and 32 and are picked up by turns of auger 30, distributed in steps and driven by a screw in the channel formed by the surface of its inner cylinder and curved guides 31 and 32. In the process of moving the glasses 3 are combined with the bottom turned upside down empty cans. Immediately after combining the jar with the glass, the operation of transferring the fish to the jar begins. To do this, there is a slope on the fist 21, with the help of which a roller connected to the piston 4 carries out a preliminary stroke of the piston 4 upward and partially moves a portion of the fish into the jar. At the time of stopping the table 2 of glasses 3 also stops bank (screw lead angle of coil 30 is equal to zero), and the cam 21 makes a turn by 90 ^to the side opposite to its direction of motion in the previous phase. Pistons 4 go up and make the final transfer of the fish in a jar. When this bank is kept from moving upward by the inner cylinder of the screw 30.

 The cans filled with fish in the bottom up position are moved by the screw 30 along the output rectilinear section of the channel formed by the guides 31 and 32 and enter the tilter 6, where they are picked up by the grippers 34 and turned into the bottom down position during the movement in the circular channel formed the surface of the cylindrical drum of the tilter 6 and the shell 40.

 From the tilter 6, the cans filled with fish are removed by estrus 8.

Claims (1)

 DEVICE FOR FILLING FISH JARS, containing a fish farmer with a vibrodrive, including an articulated plate, a connecting rod and an eccentric, a rotary table with dosing cups and pistons, a drive circular knife, a device for moving, centering and holding cans when transferring fish and a tilter, characterized in that, in order to increase productivity, simplify the design and compactness of the device, the device for moving, centering and holding the cans is mounted directly above the rotary then parallel to its plane and consists of a multi-auger screw and a pair of curved guides installed under the screw with the formation of a channel for passage of cans, and the tilter is mounted on the output end of the screw on its axis and is made in the form of a drive drum with radially located jaws for cans, while the fish farmer equipped with a flange and under it is mounted a fixed stop interacting with the latter, and the plate has an opening for the passage of the connecting rod, which is equipped with a flange for interaction with the plate.

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