DE2012615B2 - Pushing device for intermittently feeding and ejecting individual rows of containers for freezing systems - Google Patents

Description

The present invention relates to a pushing device device for freezing systems according to the preamble of the main claim.

Such a “setting device” is disclosed in US Pat 12 050 became known. With this pusher it is possible to use all freezer plates one after the other To load containers intermittently and the containers at the end of the freezing cycle also from the rear the freezer. It has, however shown that from time to time the freezer must be emptied in order to defrost them and remove accumulated ice, including all containers discharged Need to become. The pusher according to US-PS 2812 050 can not perform this operation, since their arrangement is only one. Maximum travel of the slide that is not larger than the width of the widest food container, i.e. about 12 to 13 cm. The freezer plate, however, has a free of about 180 cm. As a result, the containers have to be defrosted by hand using snow shovels similar bodies are expelled.

The object of the invention is to create a thrust device that has two thrust strokes of unequal length can perform, where the first stroke is the shorter and enough to slide a number of containers onto the freezer plate at once. The second hub the The device can run is of such a length that the freezer plate of all containers at cleared in a single movement.

To solve this problem, the invention specified in the main claim is proposed.

Further developments of the invention are given in the subclaims.

The invention is described below using an exemplary embodiment of the subject matter shown in the drawing the invention explained in more detail It shows

F i g. 1 is a front view of a continuous and automatic freezer device that is associated with the is equipped according to the invention thrust assembly;

Fig. 2 is a side view of the freezer. the front and rear endless conveyor belts being shown in section;

3 shows a horizontal section on an enlarged scale Scale according to line 3-3 in FIG. 1;

4 in a partial section a side view of a the sliding rails according to line 4-4 in F i g. 3;

FIG. 5 shows a section along the line 5-5 of FIG. 4; and

F i g. 6 one of the F i g. 4 similar bai position, with the However, parts are in the position that they will move into the Take up the inside of the free space between two freezer plates.

The housing 10 of the freezer has a suitable frame construction 11, which is an end wall 14 carries a control panel 15 on the front wall attached and this wall is also connected to an elongated, right-angled loading opening 16, while the rear wall has a similar discharge opening 18 rows of containers 20 are a right-angled or rectangular freezer plate 19 fed to a plurality of such plates in a row or a stack belongs, which are in a (not shown) frame that is in sections Moved a certain distance in the vertical direction during loading until all plates are in the Freezer are loaded. The freezing plate 19 to which the containers 20 are fed, and the Immediately above this lying freezer plate delimit a loading area, with both freezer plates rest against the container during the freezing process. To put the containers in this space between the To bring freezer plates, their distance must be increased, as z. B. in U.S. Patent 32 71 973 is given. During loading is freezing is not interrupted and during normal operation the contents of the container are on top

loaded frozen plate completely frozen when the last freezer plate is filled. At this point, a new loading and unloading process begins Ejection process, this mode of operation dragged on for days until it becomes necessary to use the freezer defrost, usually once a week.

The containers are fed to 4 loading opening 16 by means of an endless conveyor belt 21 which runs between two rollers or rollers 22 and 24 The roller 22 is provided with a belt pulley 26, that of another pulley connected to the shaft of a motor 29 via a belt 28 is driven. The upper run of the conveyor belt 21 is carried by a plate 30 which is attached to fixed Side walls 31 and 32 is attached The side wall 32 carries a flange 34 which is connected to the conveyor belt 21 and one of the freezing plates 19 lies in the same plane. The flange 34 can, as shown in FIG be a special part or it can be formed integrally with the inner side wall 32, as in FIG. 4th is shown at 34 'The lower run 35 of the conveyor belt 21 runs along a floor surface 36 of the box-like conveyor belt supports 30, 31, 32. This support is at the front of the housing of the Freezer attached by brackets 39. A similar conveyor belt arrangement is at the rear the freezer.

The pushing device has a pushing rail 40 which is attached to the front end of a pair of drive rods 41 is attached. The slide rail 40 is shown in FIGS. 2 to 4 shown as an angle iron or rail while a further rail 46 is designed like a piano hinge; it has a first, fixed, horizontal section 42, which is attached to the upper, horizontal part of the slide rail 40 and a second, articulated Section which is normally in a vertical position carries the rail 46 on its front side and serves as a push rod 44. As it moves into the freezer, this rail touches the Container 20. A hinge pin 47 is located between the section 42 and the push rod 44 vertical section 48 of the slide rail 40 limited a rearward pivoting movement of the pivotable push rod 44. When the pusher is a row of containers 20 moved from the conveyor belt 21 into the freezer, one runs at the same time incoming row with the conveyor belt 21 in front of the loading opening 16. When the decrease is then the articulated push rod 44 moved upward over the container

The drive rods 4J move horizontally from the front to the rear of the freezer. If there was enough free space in front of the freezer, equal to the depth of the Freezer plate 19 (generally about 180 cm) so the drive rods could be in straight, horizontal ones Be stored slide rails. However, there is almost always a lack of space in freezers, and from For this reason, the drive rods 41 are formed from articulated sections 49 which Articulated connections 50 and rectangular end faces 51 have, the latter being perpendicular when the Rod sections are horizontal.

Each rod section of the push rod assembly μ isl movably mounted in a slide rail construction. This construction has a lower, horizontal one Slide rail 52, for example by welding at the lower end of a square tube 54, which is mounted on the front of the housing of the freezer, is attached to the rear The end of the slide structure has an upwardly extending portion 56 that connects to the horizontal Slide rail 52 is connected via a curved section 58. The square tubes 54 carry a substantial part of the weight of the entire thrust device and can be in an adjustable position on and from being moved by means of adjusting screws 60, which protrude through slots 61 (FIG. 1) in the tubes 54, can be set. The two square tubes 54 for the lower end of the pusher are spaced by a cross piece 64 (Figure 4) held to each other.

The push rail 40 that supports the push rod 44 with the rail 46 is at 66 (Fig. 5) at each end of theirs vertical section 48 is cut off, and a short plate 68 is at the end of the horizontal section 42 of the Sckubschiene 40 with a screw or a Bolt 70 fastened between the blade 68 and the slide rail part 52 is a block or filler piece 71 arranged and these three parts are welded together The slide rail construction is through a square tube 72 reinforced and the friction between the drive rod 41 and the slide rail parts 52, 56 is made of synthetic plastic inlays 74,75,76 from z. B. polytetrafluoroethylene or other plastic The insert 75 lies between the side of the drive rod 41 and the inner wall 78 of the Square tube 72, while the insert 76 between the other side of the drive rod and the block or Filler piece 71 lies This insert 76 can move backwards along the angle iron 80 (Fig. 3) extend that the drive rods 41 to the front of the push rod 44 leads

To move the drive rod 41, one is on this attached rack is provided, which is formed from chain links 82 (Fig. 4) soft vait the Drive rod sections are welded. A drive shaft 84 is in bearing blocks 86 (F i g. 3), which at the square tubes 72 are attached, rotatably mounted and carries two sprocket drives 88 firmly connected to it. On one attached to the square tube 72 (FIG. 3) Base plate 91 is a liquid motor 90 mounted whose shaft with the drive shaft 84 via a Coupling 92 is connected. This motor 90 drives the shaft 84 and the chain wheels 88 attached to it.

For the present purpose, a liquid motor is preferred over an electric motor because of the frequent reversals of direction that are required. Pipe connections 93 and 94 connect the motor 90 (FIG. 3) with a suitable hydraulic fluid, which has controls for the rotation of the chain wheels 88 in one direction over a sufficient distance around a row of the containers 20 to be introduced into the freezer, that is, to the in F i g. 2 indicated distance from A to B. The motor is then driven in the opposite direction in order to return the push rod 44 to its original starting position.

As an example of a simple control unit for moving the liquid motor 90 back and forth, reference is made to FIG US-PS 28 12 050 mentioned at the outset pointed out. Here is a thrust device with a cylinder a piston moved back and forth by hydraulic fluid, wherein the hydraulic fluid to the cylinder under the control of a solenoid valve via lines

is fed.

As in the present case, the amount of liquid is the only factor controlling the Distance and the entire, automatically operating arrangement, including the cylinder and the Pistons can also be used for the thruster of the present invention. This pusher works more efficiently with a fluid motor, but the piston control can do the same be.

When the freezer is empty, loading begins as described in US Pat. No. 2,842,253 System. Then the top of the incoming container becomes a system with a friction wheel brought, which rotates at a higher speed than the motor, with between the friction wheel and an overrunning clutch is provided on the motor drive shaft. If a container group that has a number llHio ΛηβίπΗ ^ by a guest in their Ztiisüf

is stopped, the motor, which is mounted on a pivoting console, is tilted and closes one Contact that starts the pusher. This system works very well with the present system similar, with each freezer plate being filled in sequence.

If it is desired to defrost the freezer, this can be controlled automatically switched off and replaced by a manual control. This process closes in a simple manner a continuous movement of the drive rods 4t and the push rod 44 fully over the freezer plate 19 to position Cin F i g. 2 a. The articulated drive rod section is left for this operation 49 run on the freezer plate 19 instead of at a distance from it, as FIG. 2 shows. This can be done easily can be achieved in that the adjustment screws 60

r> be loosened and the entire thrust device something is lowered. The square end faces of the rod sections 49 prevent buckling. In fact, there isn't too much power for this one either

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Containers 20 and the freezer plate 19 is broken in the first few centimeters of the way.

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1. Pushing device for the intermittent feeding of individual rows of containers from a conveyor belt running at the front of a freezing device consisting of several superimposed freezing plates into the freezing device and for ejecting individual rows of containers from the rear of the freezing direction, the pushing device ι ο one parallel to the at the level of the loading opening located freezer plate has movable push rail, further a push rod, the m ^; 'is hinged to the pusher bar so that the pushrod and pusher bar can rise above any newly introduced containers on the freezer plate after a first row of containers has been slid into the freezer, and a motor that is used to advance and retract the Slide rail is connected, characterized in that a Vieizah! of articulated drive rods (41) between the motor (90) and the push rail (40) for advancing the same and the push rod (44) and that sliding loops (52,56) extending forward from the front of the freezer are arranged which hold the drive rods (41) for a sliding movement in order to move the pusher bar (40) completely over the freezer plate (19) so that all containers (20) are removed from the freezer in one stroke. 2. thrust device according to claim 1, characterized in that the chain links (82) r attached to the drive rods ^(41): nd, and engage the motor (90) driven sprockets {M) in the chain links. 3. Thrust device according to claim 1, characterized in that each slide rail (52) has one extending forward to accommodate the articulated drive rods (41) Section, an upwardly extending section (56) and a curved peel (58) between them. 4. Pushing device according to claim 1, characterized in that the pushing rail (40) is perpendicular is adjustable so that it can be lowered to bring the push rods (44) into contact with the To move the freezer plate (19) completely over this. 5. Thrust device according to claim 1, characterized in that the slide rails (52,56) over the drive rods (41) move, plastic inserts (74, 75, 76) to reduce friction exhibit.