The invention relates to a method for cooling a heated mould of a device for blow-moulding thermoplastic containers. The invention relates more specifically to a method for cooling a heated mould of a device for blow-moulding thermoplastic containers, the device comprising:
In the known way, moulding devices of this type can be used to create containers, such as bottles, from thermoplastic preforms. The preforms are preheated to a glass transition temperature to make them sufficiently malleable. The preform thus heated is inserted into the moulding cavity, then a blow nozzle injects a pressurized blow-moulding fluid, generally air, into the preform so that the walls of the latter conform to the impression delimited by the moulding cavity.
When the plastic containers have to be filled with a hot liquid, a container moulded at an ambient temperature carries the risk of container shrinkage and deformation. To avoid this shrinkage phenomenon, the mould has to be heated to a determined temperature, for example between 130° C. and 180° C., during the moulding operation in order to make the plastic of which the container is made heat resistant.
Various ways of heating the mould are already known. Thus, it is known practice to heat the mould using a fluidic circuit created within the thickness of the mould. A hot heat-transfer fluid is fed into the circuit in order to heat the mould.
It is also known practice to arrange heating electrical resistances within the thickness of the mould in order to heat the mould electrically.
Certain operations require an operator to handle the mould. Such is the case for example when there is a change in format of container to be manufactured. However, the operator cannot handle the mould while it is still hot and it is not a viable option to wait for the mould to cool down passively, thus bringing the entire production line to a standstill.
In order to solve this problem, it is known practice to use mould cooling means.
Thus, when the mould is heated by a hot heat-transfer fluid circuit, it has already been proposed that the hot heat-transfer fluid be temporarily replaced with cold heat-transfer fluid. Such a method allows the mould to be cooled rapidly.
The manufacture of a mould equipped with a heat-transfer fluid circuit devoted to cooling is extremely expensive and complicated to achieve because of the presence of the heating resistances within the thickness of the mould.
The invention proposes a cooling method of the type described hereinabove, characterized in that the mould is cooled by circulating a cold heat-transfer fluid directly in contact with the external face thereof.
According to other features of the method:
The invention also proposes a moulding device for implementing the method according to the teachings of the invention, in which:
characterized in that the moulding device comprises at least one controlled heat-transfer fluid feed duct which opens into the empty space to allow the heat-transfer fluid to circulate between the external face of the half-mould and the bottom of the housing.
According to other features of the device:
Further features and advantages will become apparent during the reading of the detailed description which follows, for the understanding of which reference will be made to the attached drawings among which:
In the remainder of the description, elements that have an identical structure or analogous functions will be denoted by the same reference numerals.
The following orientations will be adopted nonlimitingly in the remainder of the description:
In addition, the terms “axial” and “radial” will be used with reference to the axis “A”.
The mould 12 thus assembled has the overall shape of a hollow cylinder of revolution of vertical main axis “A”. As depicted in
Each half-mould 14, 16 is carried by an associated support 22, 24.
The half-moulds 14, 16 are articulated along a hinge (not depicted) of vertical axis so as to allow the mould 12 to be opened so that a preform can be introduced into it. A mould bottom 25, depicted in
Since the two half-moulds 14, 16 and their support 22 are substantially identical, only the half-mould 14 and its support 22 will be described hereinafter with reference to
The half-mould 14 has a semi-cylindrical shape. It thus has a planar front union face 26 in which half of the moulding cavity 18 is formed, and an opposite semi-cylindrical external face 28 that forms half of the external face 20 of the mould 12, as illustrated in
If reference is made once again to
A mounting plate 34 of complementary shape is fixed to the upper face 30 of the half-mould 14. The upper face of the mounting plate 34 forms a support face for a nozzle (not depicted) carrying pressurized air by virtue of which the container is blow-moulded.
The half-mould 14 comprises controlled means for heating the mould to a determined temperature. More specifically, the heating means here are formed by heating electric resistances 35 which are interposed within the thickness of the half-mould 14 between the moulding cavity 18 and the external face 28.
For this, the half-mould 14 comprises a plurality of vertical orifices 36 which open at the top into the upper face 30 of the mould, as can be seen in
The half-mould 14 is housed in a housing 40 which is made in a front face of the associated support 22, as depicted in
The removable attachment is achieved using means that are already well known. One exemplary embodiment of such attachment means is described and depicted in document EP-B1-0.821.641.
The half-mould 14 needs to be kept hot. To avoid heat loss, as depicted in
This space 44 is usually filled with stationary air forming a thermally insulating layer. Advantageously, the spacer pieces 46 offer a more reliable possible area of contact with the external face 28 of the half-mould 14 for minimizing heat loss by conduction. For the same reasons, the spacer pieces 46 are advantageously made of a thermally insulating material.
The empty space 44 is made as one piece, i.e. the spacer pieces 46 do not divide it into several separate parts.
The empty space 44 is not fluidtight, thus it can communicate with the outside, notably via the front gaps 48 formed between the vertical edges of the union face 26 of the half-mould 14 and the vertical edges of the housing 40 as depicted in
When the heating means are activated they heat the half-mould 14 to a temperature that is too high for an operator to be able to handle it bare handed. The temperature of the half-mould 14 is, for example, in excess of 100° C.
When the half-moulds 14, 16 need to be handled, it is therefore preferable to deactivate the heating means. Nonetheless, this operation is not enough because the passive cooling of the half-mould 14 is a very slow process.
The invention therefore proposes a method for actively cooling the half-mould 14. This method is implemented after the heating means have been deactivated.
According to this method, the half-moulding 14 is cooled by circulating a cold heat-transfer fluid directly in contact with the external face 28 thereof. The heat-transfer fluid in this instance circulates in the empty space 44.
To do this, at least one controlled heat-transfer fluid feed duct 50 opens directly into the empty space 44 to allow the heat-transfer fluid to be circulated between the external face 28 of the half-mould 14 and the bottom 42 of the housing 40. In the example depicted in
Each feed duct 50 here extends vertically within the thickness of the support 22, parallel to the bottom 42 of the housing 40. Each feed duct 50 is positioned near to a vertical lateral edge of the housing 40.
Each feed duct 50 comprises at least one orifice 52 opening into the bottom 42 of the housing 40. Each feed duct 50 here comprises three orifices 52 opening out as depicted in
Each orifice 52 is here arranged vertically between two spacer pieces 46 so as to allow an even distribution of the stream of heat-transfer fluid despite the presence of the spacer pieces 46.
Each feed duct 50 is connected to a source or heat-transfer fluid via connecting means 54 which are arranged at a lower end of the support 22.
The heat-transfer fluid here is formed by a pressurized gas which is discharged into the atmosphere by passing through the gaps 48. The pressurized gas in this instance is compressed air, for example at between 8 bar and 40 bar.
The gaps 48 have a passage cross section that is large enough that the pressurized gas is made to expand as it circulates against the external face 28 of the half-mould 14. This expansion causes a drop in the temperature of the gas thereby encouraging rapid cooling of the half-mould 14 by conducting heat from its external face 28 to the gas.
This allows the heat of the half-mould 14 to be removed into the atmosphere very rapidly.
The method is advantageously implemented with the two half-moulds 14, 16 parted from one another to allow the heat-transfer fluid to be discharged at maximum flow rate.
The device and the method for implementing it can thus effectively cool hot moulds 12. For example, by using compressed air at 8.5 bar as the heat-transfer fluid, it is possible to cool several moulds 12 in under 15 minutes at a very low cost because of the relatively low pressure of the heat-transfer fluid.
By increasing the pressure of the heat-transfer fluid it is of course possible to shorten the time taken to cool the moulds 12 even further. This is because the flow rate of heat-transfer fluid can be increased and it is possible to obtain a heat-transfer fluid that is very cold because of the great amount of expansion it has undergone.
Furthermore, the external face 28 of the half-mould 14 has a larger surface area than the internal face of the cavity 18. Thus, by circulating the heat-transfer fluid against the external face 28 of the half-mould 14, it is possible to benefit from a larger area of contact between the heat-transfer fluid and the half-mould 14. The removal of heat by conduction is thus greater than it would be if the heat-transfer fluid was circulated inside the moulding cavity 18.
Number | Date | Country | Kind |
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1258026 | Aug 2012 | FR | national |