HU199347B - Device for setting-up jars particularly preserves-industrial hollow glaswares - Google Patents

Abstract

Structure glasses, especially canning for resting the bay glasses, lying down preferably carrying bottles (4) in position spherical conveyor belt (2). as well the latter is perpendicular to the latter, retracted dispensing tape for bottles (4) (3). Its essence is that the spherical conveyor (2) retracted recovered glass (41 overturning prevent and transmit, a spherical conveyor belt (2) in connection with drive (1), the bottle (4) overturns against spherical conveyor belt (2) or the guide bar for the screw (1) (8) and the spherical conveyor (2) the bottle (4) is removed by the snail (1) a deflector flange guiding the first groove section (10) (71 is.

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for adjusting bottles, in particular canning bottles, having a conveyor belt, preferably carrying a spherical conveyor, and a conveyor belt conveying the canted glass perpendicular to the conveyor belt.

In the case of the known and commonly used equipment in the canning industry, the glasses are placed in so-called goblets in a lying position.

The weight distribution of glass filled with merchandise - filled with filler or other filler - is inhomogeneous, so its center of gravity position is constantly changing during installation.

In the case of known devices, the conveyor belt, preferably spherical, conveying the glasses lying in position is connected perpendicular to the conveyor belt conveying the stationary glasses. There is a difference in level between the two tapes. The speeds of the two belts vary in size and direction.

For the reasons described above, a significant percentage of glasses in hitherto known apparatuses are overturned, some of which break, resulting in significant time and material loss.

Another known apparatus comprises a rotary table which rotates at a constant angular velocity such that its angular acceleration is substantially zero. Given that the angular acceleration is zero, the tangential acceleration is also zero. However, the centrifugal force due to normal acceleration exerts a tilting torque on the glass, which is constantly changing in size during coating, and due to the constant displacement of the center of gravity of the filled glass, the glass will still be tilted or broken.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a structure that prevents roll-over or breakage of filled glass and eliminates the time and material losses resulting therefrom.

Our invention is based on the recognition that forces must be created that act in the opposite way to those causing glass to fall. In the structure of the present invention, the problem of glass rollover is solved by substantially breaking forces, such as frictional forces between the glass and the metering belt and baffles, and reaction forces between other structural members.

The object is achieved by a device according to the invention, which prevents and conveys the roll-over of the recovered glass which is removed from the spherical conveyor, is in contact with the spherical conveyor, it has a baffle guide to the auger groove.

In a preferred embodiment of the device according to the invention, there is a worm with a groove of a diameter dependent on the diameter of the glass, a helical groove forming a continuation of this groove and a groove tangentially connected to the glass.

In preferred embodiments of the device according to the invention, the radius of the groove of the screw against the spherical conveyor is at least 2 mm greater than half the diameter of the glass, i.e.

B> _z - + 2mm.

In other preferred embodiments of the device according to the invention there is a kinematic link formed by a chain drive between the spherical conveyor and the screw.

In the structure according to the invention, it is advantageous to have an interchangeable, constant bearing distance, preferably of plastic construction. application of snails.

The structure of the invention is an example only! Embodiments of the invention will now be described in more detail with reference to the accompanying drawings, in which:

Fig. 1 is a schematic top plan view of an exemplary embodiment of the present invention;

Figure 2 is a side view of the structure of Figure 1.

Figure 1 is a plan view of a structure according to the invention. It can be seen that the structure is essentially a rollover conveyor 1, which conveys the bottles 4 from the conveyor 2, which conveys the lying bottles 4, preferably from a conveyor belt 2, It is formed of protective guide strips 8 and a baffle plate 7 which is connected to the conveyor belt 2 and which guides the bottle 4 to the groove section 10 of the screw 1. The worm 1 is in driving engagement with the spherical conveyor belt 2 by means of a chain drive 5, i.e. the rotary movement of the worm 1 is provided by the chain drive 5.

The screw 1 has essentially three groove sections. The first groove section 10 is located opposite the spherical conveyor belt 2. Its function is to support the raised bottle 4, which has been removed from the spherical conveyor belt 2, from tipping and preventing tension. The size of the groove section 10 is always dependent on the diameter of the glass 4. Experiments have shown that the radius of the groove section 10 must be at least 2 m larger than the radius of the glass, i.e. half the diameter. 3

GB 199347 Β: A groove section 11 is connected to the groove section 10, which is formed in spiral lines and • runs around the periphery of the screw.

The pitch of the groove section 11 was also selected as a function of the diameter of the glass 4. The pitch of the groove section 11 is such that the groove section 11 rises d + 5 mm per half turn of the screw, where d is the diameter of the glass 4.

The third groove section 12 is located at the end of the screw 1 and is configured to be tangentially connected to the glass 4 conveyed by the screw. Thus, the bottle 4 is smoothly introduced into the guide strips 8. Such a design of the snail 1 with absolute certainty prevents tension and tipping of the glasses 4.

The rotary movement of the screw 1 is secured from the spherical conveyor belt 2 by means of a chain drive 5. The correct direction of rotation of the auger 1 is achieved by means of a 1: 1 modification (cf. Fig. 2), and the chain drive 5 and the gearwheel 6 are provided with a guard 9 to eliminate the risk of an accident.

The jars used in the canning industry have varying diameters. Therefore, depending on the type of glass used and the diameter of these glasses, different screws are used. The pulleys are designed interchangeably and the bearings 13 of the pulleys have a constant bearing spacing.

The modification of the chain drive 5 should be chosen such that the glass coming from the convex conveyor 2 at a speed of vi takes the time corresponding to the height of the glass in which the screw 1 turns. This ensures that the glasses 4 do not collide with each other.

The operation of the device according to the invention is as follows:

At point A, the lying glass 4 moves at a uniform velocity vi on the spherical conveyor 2. From now on, the bottle 4 will roll down at point B onto the feed belt 3. The baffle plate 7 ensures that the center axis of the stationary glass 4 at point B lies in the center line of the track defined by the guide bars 8.

In the case of known structures, it is usually at this moment that the glass 4 overturns. In the present invention, however, a screw made of a suitably plastic material and a baffle plate 7 prevent tipping. The 4 bottles are prevented from being tilted partly by means of a lock (snail) and partly by an erosion lock (baffle).

As mentioned, the screw 1 has a groove section 10 in its portion opposite the spherical conveyor belt, which is substantially aligned with the position B.

The bottle 4 is actuated by the conveyor belt 3 in the proper position of the screw 1. After making a relatively short Moorish route, the glass 4 is moving towards point C at a speed corresponding to the speed and pitch of the screw 1.

The glass 4 at point C fits into the groove section 12 of the screw 1 which is tangential. After passing through point C, the glass 4 passes unhindered on the dispensing belt 3 delimited by the guide strips 8.

The velocity vi of the spherical conveyor belt 2 and the velocity v z of the conveyor belt 3 are such that, when the glass 4 has passed the screw 1, i.e. at point C, the next 4 glass arrives at the conveyor belt 3, i.e. at point B.

An advantage of the device according to the invention is that it completely eliminates the possibility of glass overturning or breaking. This saves significant time and material loss.

A further advantage of the device according to the invention is that it can be easily fitted to known, already existing devices, with minor modifications thereof.

Claims (6)

A device for recovering bottles, in particular canning bottles, having a conveyor belt, preferably conveying glass for lying, and a conveyor belt conveying from the conveyor belt, perpendicular to the conveyor belt, 10 screws (1) for preventing and transferring 10 staggered glass (4) in contact with the spherical conveyor (2), for connecting the bottle (4) to the roll conveyor (2) and for the screw (1) 15 a guide plate (8) and a glass (4) guiding the spherical conveyor (2) out of the spherical conveyor (2) into a first groove section (10) of the screw (1). 20 Device according to Claim 1, characterized in that the receiving portion of the ball belt conveyor (2) has a first groove section (10) of a size dependent on the diameter of the glass (4), formed in the form of a helical line extending this groove section 25 (10). a screw (1, 30) having a groove section (11) and a third groove section (12) tangentially connected to the glass (4). Device according to Claim 1 or 2, characterized in that the radius (R) of the first groove section (10) of the screw (1) in relation to the spherical conveyor (2) is at least 2 mm 35 greater than half the diameter of the glass (d). , that is, d R> - + 2 is selected according to the formula. 40 4. A device according to any one of claims 1 to 4, characterized in that it has a chain drive (5) providing a kinematic connection between the spherical conveyor (2) and the screw (1). 45 5. A device according to any one of the preceding claims, characterized in that it has a plurality of interchangeable screws (1) of the same bearing spacing and of different size. 6. The structure according to any one of claims 1 to 5, characterized in that it is a plastic structure! has a screw (1).