SE464472B - SET AND DEVICE FOR MANUFACTURE OF HIGHLY GLASS PRODUCTS - Google Patents

Description

f »464 472 the bottom of the bottle, this must be cooled very efficiently, which is done externally by means of said upward air flow.

The manufacturing speed of the machine must be adjusted so that the required cooling is achieved before the bottle is lowered for further transport.

EP-A2-0 071 825 describes a machine for manufacturing glass bottles, in which also some cooling of the glass bottles takes place internally by means of air or other gas. According to the description, air is then injected into the bottle by means of a nozzle located above its mouth. As a result, however, no effective cooling can be achieved, in particular not from the bottom of the bottle, since air with the same temperature as the ambient is used, and it is supplied freely through the same narrow opening through which the return air is to escape. It should be noted that the pressure that can be applied to injected air is limited by the risk of further inflation and deformation of the still deformable bottle.

A main object of the present invention is to be able to achieve a significantly more efficient internal cooling of the bottle and its bottom when manufacturing glass objects according to the above without risk of deformation thereof. In this way, the production speed can be increased and / or the quality of the end product can be improved.

Another object is to provide a device for use in applying this method.

According to the present invention, the above-mentioned object can be achieved by supplying a gas in a liquid state to the interior of the glass object, where it may be evaporated while absorbing heat from the glass. The gas must be selected so that the pressure in the bottle does not increase significantly at the same time as the temperature of the gas in the liquid state should not be too low, as this complicates material and component selection and increases the risk of malfunctions. Furthermore, the gas should have a high heat capacity, so that the amount of gas that must be supplied for efficient cooling can be kept small.

The special characteristic of a method of the type specified in the first paragraph in the description, which meets the above-mentioned requirements, is that the internal cooling takes place by adding carbon dioxide in liquid form to the cavity of the object where part of the carbon dioxide due to the atmospheric pressure prevails. first solidifies and then gasifies while cooling the glass.

The utilization of carbon dioxide is very advantageous, as it e.g. can be supplied at a pressure of about 15 bar, which means a temperature of about minus 40 ° C. The solid phase, carbon dioxide snow, obtained during spraying at the atmospheric pressure prevailing in the bottle, has a lower temperature of about minus 76 ° C, which gives an effective cooling effect, as the amount of energy required for evaporating carbon dioxide snow is very high per unit weight. .

It is preferred that the carbon dioxide is ejected through a probe made with at least one fluid channel, which is inserted so deep into the cavity in the glass object that an internal cooling of the bottom part of the object is also achieved. To achieve the best cooling effect, the carbon dioxide is sprayed in different directions over the bottom of the object.

In order to increase the production speed, in a preferred embodiment of the method, the probe is inserted into the cavity during the movement of the object from the mold to a position in which an external cooling of the bottom of the object takes place.

The particularly characteristic of a device for use in carrying out the method is stated in the claims.

The invention will be described in more detail below with reference to the accompanying drawings.

Fig. 1 schematically illustrates the first two steps in 464 472 conventional bottle manufacturing.

Fig. 2 schematically illustrates a device according to the invention for cooling a bottle manufactured according to Fig. 1.

Fig. 3 shows on a larger scale an embodiment of a probe included in the device according to Fig. 2.

In Fig. 1, 1 denotes a bottle blank formed in a first mold, which is supplied to glass mass. The bottle blank 1 is formed upside down and it is held at its neck even after the mold (not shown) has been removed. By means of a lever 4 pivotally mounted about a shaft 3, the bottle blank 1 is transferred to a divisible final mold 5. In the final mold, the bottle blank is inflated to the final bottle mold. The final mold is then opened and the bottle is gripped around the neck and transferred to a cooling chamber for cooling.

For the transfer of the finished bottle from the mold 5 to the cooling chamber (not shown), a device according to Fig. 2 is used according to the present invention. In this, 6 denotes a box which, i.a. carries gripping means 7 for co-operation with a finished bottle 8. Furthermore, the box 6 carries a probe 9, which can be lowered into a bottle held by means of the gripping means 7.

To allow the required vertical movement of the probe 9, it is connected to a flexible low temperature hose 10.

The end of the hose 10 which is not connected to the probe 9 is connected to an insulated feed hose 11 from a carbon dioxide container 12, which hose is also flexible to allow movements of the box 6.

The box 6 is supported by an arm 14 which can be articulated around a shaft 13 in order to be able to be transferred between a retrieval position and a cooling and delivery position.

The above-described device for transferring and cooling a bottle operates in the following manner. When a bottle of 8 is blown f! 464 4-72 up to the final shape in the final mold 5, the box 6 is lowered down towards the bottle so that the gripping means 7 can grip the neck of the bottle.

At the same time, the probe 9 is lowered relatively deep into the bottle 8. Then a valve (not shown) is opened, so that liquid carbon dioxide from the container 12 is supplied to the interior of the bottle via the probe 9 at the same time as the bottle is transferred to the solid line in fig. 2, in which the bottle 8 hangs above a nozzle device 15, which blows cooling air towards the outside of the bottom of the bottle. After a few seconds in this position, the bottle 8 is transferred, for example by means of a piston 16, to a conveyor belt 17, which transports the bottle to a cooling chamber (not shown).

From the enlarged view in Fig. 3 it appears that the probe 9 in the embodiment shown comprises four separate channels, suitably in the form of separate tubes 18 with small dimensions to keep the outlet pressure low and to avoid inflating and deforming the bottle. The lower parts of the tubes 18 are bent out to achieve a good spread of the carbon dioxide over the bottom of the bottle.

As stated in the introduction, the use of carbon dioxide as a cooling medium is very advantageous, as carbon dioxide can be supplied at a moderately low temperature at a manageable pressure, in addition to which carbon dioxide is sprayed into the bottle where atmospheric pressure prevails. lower temperature than the added carbon dioxide.

This thus means that a lower temperature is achieved and thus a more efficient cooling effect in the bottle than corresponds to the temperature for which pipes and components used for the supply of carbon dioxide to the bottle must be adapted.

As an example, liquid carbon dioxide can be supplied at a temperature of about minus 40 ° C with a pressure of 15 bar.

During the conversion to carbon dioxide snow in the bottle, the temperature drops to about minus 76 ° C, which gives a very effective cooling effect. Carbonic acid snow also has a very high heat capacity and as an example it can be mentioned that for decoction of 1 kg liquid nitrogen at atmospheric pressure 199 kJ is needed while for decoction of 1 kg carbon dioxide snow 573 kJ is needed. In addition to the above-mentioned technical advantages of the utilization of carbon dioxide, this thus also entails significant advantages from a cost point of view.

Using a probe of the shown embodiment placed with its outlet openings at a suitable distance from the bottom of the bottle, the formed carbon dioxide snow will be gasified and emit in the form of gas before it reaches the bottom of the bottle. The pressure increase in the bottle becomes very moderate, not exceeding about 0.02 bar, which does not involve any risk of deformation of the bottle.

Using the method described above, in experiments with the supply of carbon dioxide for about 4 seconds. achieved an extra temperature drop at the bottom of the bottle by about 30 ° C, which means great advantages, as the hardening of the glass mass and thus the stability of the bottle increases rapidly with lowered temperature within the area of interest. This means that the production speed and / or bottle quality can be further increased.

This also contributes to the fact that the cooling of the interior of the bottle can take place during the movement of the bottle from the finished mold 5 to the delivery position, which can mean an extra cooling time of about 4 seconds. The already existing internal cooling of the bottle can thereby mean that the time the bottle normally hangs above the nozzles for the external bottom cooling can be reduced. The invention has been described above in connection with the embodiment shown in the drawing. However, this can be varied in several respects within the scope of the claims. Thus, for example, the means for gripping and moving the bottle can be varied as well as the device used for supplying carbon dioxide to the bottle. It is only important that liquid carbon dioxide can be efficiently supplied to the bottle for cooling its interior and especially the bottom part as soon as the bottle has been formed, but without prolonging the time in the finished mold.

Claims (9)

464 472 PATENT CLAIMS 1. In the manufacture of hollow glass objects, such as bottles and cans, using at least one molding equipment, in which each object, after being removed from the mold but before being set down for transport to a cooling chamber or the like, is both cooled - as internally by means of a fluid, characterized in that the internal cooling takes place by adding carbon dioxide in liquid form to the cavity of the object where a part of the carbon dioxide as a result of the atmospheric pressure prevailing in the cavity first changes to solid form and then gasifies during cooling of the glass. 2. A method according to claim 1, characterized in that the carbon dioxide is ejected through a probe made with at least one fluid channel, which is inserted so deep into the cavity that an internal cooling of the bottom of the object is primarily achieved. 3. A method according to claim 2, characterized in that k0h fi LKiüH1Ut¶3IÉaS through several small openings in different directions over the bottom of the object. 4. A method according to claim 2 or 3, characterized in that the probe is inserted into the cavity during the movement of the object from the mold to a position in which an external cooling of the bottom of the object takes place. Device for use in the manufacture of hollow objects of glass, such as bottles and cans, comprising at least one molding equipment (5) for the intended object, which device further comprises means (9-12; 15) for both external and internal cooling of each object (8) by means of a fluid after it has been removed from the mold but before it is set down for transport to a cooling chamber or the like, characterized in that the device for said internal cooling comprises means (9-12) for supply of carbon dioxide in liquid form to the cavity of the object (8), which carbon dioxide, due to the atmospheric pressure prevailing in the cavity, at least to some extent first turns into solid form and then gasifies during cooling of the glass. Device according to claim 5, characterized in that it comprises a probe (9) made with at least one fluid channel, which is arranged to be inserted so deep into the cavity that an internal cooling of the bottom of the object (8) is primarily achieved. Device according to claim 6, characterized in that the probe comprises a plurality of fluid channels (18), the mouths of which are directed in different directions over the bottom of the object (8). Device according to claim 7, characterized in that said channel mouths have a small flow area. Device according to any one of claims 6-8, characterized in that it comprises means for inserting the probe (9) into the cavity during the movement of the object (8) from the mold (5) to a position in which an external cooling of the bottom of the object takes place.