阅读说明：本技术 型坯成型容器的成型机的加热通道的加热模块的主反射器 (Main reflector of heating module of heating channel of parison forming container forming machine ) 是由 M·林克 F·莱温 D·菲尔绍 D·乌卢蒂尔克 N·迈耶 于 2018-09-06 设计创作，主要内容包括：本发明涉及一种加热模块(10)和一种用于模制机中的加热管的加热模块的主反射器,该模制机用于从预成型件生产容器,其中,加热模块热塑性预成型件,其中,提供了所述主反射器。在管状加热装置之间平行地布置在管状加热装置之间,该管状加热装置在加热模块的侧壁(11、12)上并发射红外线,侧壁由陶瓷材料构成,其特征在于,主反射器(16)通过燕尾连接而连接至侧壁(41),其中,在反射器(51,51’)上分别形成燕尾型连接区域(52、52’),每个区域可以通过固定在侧壁上的卡扣件(42)固定,卡扣件(42)由钢制成,尤其是弹簧钢,尺寸与燕尾形匹配。(The invention relates to a heating module (10) and a main reflector of a heating module for a heating tube in a moulding machine for producing containers from preforms, wherein the heating module thermoplastically moulds the preforms, wherein said main reflector is provided. Arranged in parallel between the tubular heating means on the side walls (11, 12) of the heating module and emitting infrared light, the side walls being composed of a ceramic material, characterized in that the main reflector (16) is connected to the side walls (41) by means of a dovetail connection, wherein dovetail-shaped connecting regions (52, 52') are formed on the reflectors (51,51'), respectively, each region being fixable by means of a catch (42) fixed on the side wall, the catch (42) being made of steel, in particular spring steel, the dimensions of which match the dovetail shape.)

1. A heating module for a heating channel of a moulding machine for producing containers from parisons, in which a parison consisting of a thermoplastic is heated, having two opposite side walls, preferably also a base and an upper cover,

wherein a main reflector is arranged between a tubular heating device arranged parallel and above one another on one side wall of the heating module and this side wall, said tubular heating device outputting infrared radiation, and optionally a bottom reflector is arranged in the bottom region and a counter reflector is arranged on the opposite side wall,

wherein at least the main reflector is made of a ceramic material,

it is characterized in that the preparation method is characterized in that,

a main reflector (51) is connected to the side wall by a dovetail connection,

wherein, in each case, a dovetail-shaped connection region (52, 52') is formed on the reflector (51,51'), which can be fixed in each case by means of a clip (42) which is fastened to the side wall (41) and is made of steel, in particular spring steel, and has dimensions adapted to the dovetail.

2. The heating module of claim 1,

it is characterized in that the preparation method is characterized in that,

the base reflector (18) and/or the side reflectors (19) are made of ceramic material and are connected to the base region (13) or the opposite side wall (11) by means of a respective dovetail connection, as defined in claim 1.

3. The heating module of claim 1 or 2,

it is characterized in that the preparation method is characterized in that,

the catch (42) has a nominal bending region (49, 50) in which the catch primarily bends under force.

4. The heating module of one of claims 1 to 3,

it is characterized in that the preparation method is characterized in that,

the catch (42) is longer than the dovetail (52, 52') to be held by the catch.

5. The heating module of claim 4,

it is characterized in that the preparation method is characterized in that,

the snap-in element (42) is designed to be longer than the dovetail (52, 52') in the range of 1% to 15%, preferably 2% to 10%.

6. Heating module according to one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

the main reflector (51) is constructed from a plurality of segments connected to the side wall by a respective dovetail connection.

7. A main reflector for a heating module, in particular for a heating tunnel of a moulding machine for producing containers from parisons, according to claims 1 to 6, in which a parison consisting of thermoplastic is heated,

the main reflector is arranged between a tube-shaped heating device which is arranged on one side wall of the heating module in parallel and above each other and the side wall and is made of ceramic material, the tube-shaped heating device outputs infrared radiation,

it is characterized in that the preparation method is characterized in that,

in the main reflector (16) there is a channel (17) which extends horizontally in the direction of the heating channel,

wherein each channel (17) is configured with respect to its contour and its dimensions: so that heating means (15) for heating the module (10) in said channel can be arranged: such that each channel (17) surrounds with its walls a portion of the periphery of a heating device (15).

8. The main reflector as set forth in claim 7,

it is characterized in that the preparation method is characterized in that,

the main reflector is constructed from a plurality of sections.

9. The primary reflector of claim 8,

it is characterized in that the preparation method is characterized in that,

the sections each correspond to a subsection of the main reflector (16) along a vertically and/or horizontally running parting line (23, 24).

10. The main reflector as set forth in claim 9,

it is characterized in that the preparation method is characterized in that,

the sections correspond to subsections defined along horizontal and vertical directions.

11. The primary reflector of claim 10,

it is characterized in that the preparation method is characterized in that,

the segments (26) each have a horizontally running intermediate strip (27) which points into the heating channel and the two longitudinal sides of which are each designed as a wall section (28, 29) of the channel, so that two segments (26) which are arranged one above the other and one behind the other together form the contour of a complete channel.

12. The primary reflector of claim 11,

it is characterized in that the preparation method is characterized in that,

the free ends (30, 31) of the wall sections (28, 29) of the channel are provided with a uniform chamfer on both sides.

13. The main reflector of one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

on its rear side, a connection region (30, 46) is formed on the main reflector or on the section (26), said connection region being able to be fastened to a counterpart (42) associated therewith and arranged on the side wall (41).

14. The primary reflector of claim 13,

it is characterized in that the preparation method is characterized in that,

the connection region (46) formed on the main reflector (45) or the section has a dovetail shape, and

the counterpart is a catch (42) made of spring steel.

Technical Field

The invention relates to a heating module according to the preamble of claim 1 and to a main reflector according to the preamble of claim 7.

Background

In general, heating modules of this type are set in a moulding machine for producing containers from parisons, wherein a parison consisting of a thermoplastic is first heated and then, after heating, the desired shape (for example the shape of a bottle) is achieved by means of blow moulding or by means of a filling.

Such machines, which are also referred to as stretch blow molding machines (blow molding), usually have a revolving conveyor device, by means of which the parisons are guided through a heating tunnel via defined sections of the conveying path for thermal conditioning (thermo konditioning). In this case, the parisons (or the regions thereof projecting into the heating channel) are heated to a temperature above the glass transition point (Glaspunkt) of the material to be treated. The same type of equipment for the temperature regulation of the parisons can also be used in machines that simultaneously effect the forming and filling of containers made from parisons.

Naturally, such devices can also be considered: in these apparatuses, for example, vertical heating (stehendebeheizing) takes place.

In general, the heating channel is formed by at least one heating module, and in the case of moving heating, the heating channel is then typically formed by a plurality of heating modules arranged one behind the other in the conveying direction and connected to one another, wherein each heating module forms a section of the heating channel.

A typical heating module defines a radiation space defined by two side walls opposite to each other, a bottom and an upper cover. In the region of one of the side walls of the heating module, a heating element is provided, typically horizontally oriented, tube-shaped heating devices arranged one above the other in the vertical direction, which emit infrared radiation. A reflector, referred to as a main reflector, which is provided on this side between the heating device and the side wall serves for: the radiation directed backwards from the heating element is reflected back into the heating module in the direction of the parison. Instead of the term "main reflector", the term "primary reflector" is also used in the literature of the art.

Further reflective elements, which are generally referred to as counter reflectors and bottom reflectors, are provided on the respective sides and in the bottom region of the heating module.

The task of these reflectors is to ensure that the parisons are heated in the heating module with as low a heat loss as possible.

These reflectors may be made of different materials, such as aluminum or ceramic.

The invention is directed to a reflector, in particular a main reflector, made of a ceramic material.

The technical problem is that ceramic components (e.g. heated reflectors) have relatively large manufacturing tolerances. In the known heating modules, the reflectors are arranged, for example, in a frame or rail, wherein too small reflectors can wobble, while too large reflectors require additional machining, which is relatively complex.

Disclosure of Invention

The object of the invention is to improve such a heating module in such a way that a simpler holding and fixing of the reflector is possible.

A further object of the invention is to provide primary reflectors by means of which a more effective radiation effect can be achieved.

This object is achieved by a heating module having the features of claim 1 and a main reflector having the features of claim 7.

A first aspect of the invention relates to the fastening of, in particular, the main reflector to the side wall of the heating module. The main reflector can, as described below, also be constructed from individual sections, which can be fixed accordingly. It is conceivable to form a connection region on the rear side of the reflector (or of the segments), which can be inserted into a corresponding receiving region on the side wall, for example according to the slot-and-key principle. Particularly preferably, a dovetail-shaped connection region is formed on the reflector (or on the segments), which, as described further below, can be accommodated according to the invention in a corresponding catch (span) on the heating module, which catch is made of steel, in particular spring steel. In particular, if the catch is produced from a thermally stable spring steel and is correspondingly profiled (kontourier), tolerances in the production of the reflector (or of the sections) and possible thermal effects during the heating and cooling of the heating module can be compensated well by means of such a connection.

This aspect is not necessarily limited to the main reflector, but can also be used in general for heating ceramic reflectors in modules, for example counter and bottom reflectors. This may relate to reflectors having the usual shape and properties, but may also relate to primary reflectors as described further below.

In a heating module designed according to one aspect of the invention, the connection between the reflector (or reflector segment) and the side wall is thus realized by means of a dovetail connection by means of a universal clip made of steel (in particular spring steel), which receives the reflector (or its segments) in the case of ceramic materials within the usual tolerances in terms of manufacture, without the clip having to be adapted individually to each segment (or each reflector) for this purpose. The profile and the pretension of the snap-in element are adapted to the dovetail and the reflector (or the segments) is fixed by three contact surfaces.

One or more regions of elastic nominal bending can advantageously be provided in the clasp. The bending-rated region refers to a region in which: the fastener is mainly used under the action of forceIn these regions, the spring bends, while the other regions of the clasp retain their original orientation. Thereby it is achieved that: the catch can compensate for tolerances in the dovetail and at the same time bear on the dovetail over as large an area as possible and effectively fix it. Such a nominal bending region can thus be set, for example, already during the production of the clip, by the pre-bending already being provided there or by the clip material being embodied here in a manner that it is easier to bend by other means

By using spring steel, which is advantageously resistant to high temperatures, the reflector (or a section thereof) remains fixed after the temperature influence by the snap-in element.

Advantageously, mass-produced clips made of spring steel can be used without further deformation being required for engagement of the clip with the dovetail.

It is also advantageous if the catch is embodied longer than the dovetail to be held by it. In this case, not only is there no form fit between the dovetail and the clamping portion, but rather the catch should protrude beyond the dovetail and then return. In this way also the elastic retention properties of the clamping portion are improved. The catch can be embodied longer than the dovetail, for example by 1% to 15%, preferably 2% to 10%, preferably more than 5%. This means that the region of the locking element between its legs (Schenkeln) is longer than the distance between the upper and lower edges of the dovetail.

A second aspect of the invention relates to the main reflector. According to the invention, it is therefore provided that recesses or channels separated by webs (Stegen) are provided in the main reflector in the horizontal direction, i.e. in the transport direction along the transport path through the heating modules. The contour and dimensions of the channels are selected such that in the channels, each of the tubular heating means can be arranged such that the channels surround a portion of the circumference of the tubular heating means.

Usually, these channels are dimensioned such that their wall regions extend, for example, over half the circumference of the heating tube. Channels are contemplated and naturally encompassed by the present invention but also such: these channels cover a smaller or larger area. It is also not mandatory that the channels have a partially circular profile. Naturally also V-shaped profiles or angular profiles are conceivable, just to name a few examples.

The same applies to the heating device. Generally, a tubular radiator is referred to herein. But naturally other shapes are also conceivable.

However, the invention generally relates to heating tubes arranged one above the other and parallel to each other, which are each accommodated in a channel of a main reflector arranged between the heating tubes and a side wall.

An important advantage of the invention is that the radiation directed backwards from the heating device (i.e. in the direction of the side walls) is concentrated and reflected back as far as possible into the radiation space of the heating module. Losses due to diffuse reflection (as they occur, for example, in reflectors with smooth surfaces) are minimized here. The webs between these grooves are used here as shaded edges (Schattenkanten) and for radiation limitation.

The handling of ceramic materials is not without problems. As the dimensions of components, which are usually produced by sintering, increase, for example, the risk of fracture and the production tolerances, which are determined by the production, also increase.

One embodiment of the invention provides that the main reflector is not formed from a single piece, but from a plurality of subsections. These subsections can generally be produced more simply and more reproducibly with less risk of breakage.

For example, in a further embodiment of the invention, it is conceivable for the segments to correspond to subsections of the main reflector along vertical and/or horizontal parting lines.

One possibility is, for example, to combine the reflector from a plurality of vertically running sections.

Naturally and as described below, additional divisions along one or more horizontal split lines are also possible. A particularly preferred embodiment of the invention relates to a main reflector which is formed from segments which each correspond only to subsections of the main reflector which are delimited in the horizontal and vertical direction.

According to a preferred embodiment, it is provided that the segments each have a horizontally running intermediate web which points toward the heating channel. From this intermediate bar extend the wall sections of the channel, but these wall sections correspond only to a part of the contour of the channel. In the simplest case, this wall section defines half the contour of the channel. In this case, the reflector can be constructed from identical segments, wherein two respective segments lying one above the other define a complete channel. In other words, the respective two sections share one channel in the vertical direction. In the horizontal direction, these sections can be arranged adjacent to one another until the desired reflector width is reached.

As already mentioned, it is advantageous if these sections in the design concerned each provide half of the channel contour on both sides of the intermediate bar. The reflector can then be constructed in a particularly simple manner from the same segments. However, it is also conceivable for the wall sections extending from the intermediate webs to have different dimensions. The reflector can also be constructed from the same sections. However, it is necessary to take into account the orientation of the sections when joining them, which makes the costs slightly higher.

Independently of this, an important advantage in this design of the sections is that the intermediate bar is relatively thin, i.e. it can be produced with the smallest possible thickness in the processing of the ceramic material. If the separating plane (as it is also possible) extends through the intermediate strip, the two parts of the intermediate strip of the participating mutually adjoining sections should each have a respectively defined minimum thickness, which can lead to an undesired thickness and thus to a correspondingly greater vertical spacing of the heating radiators. Furthermore, it is sufficient in this embodiment to be able to replace a section in order to change the length and width of the intermediate strip. The length (i.e. the extent into the radiation space) and the width of the intermediate strips are two important parameters which influence the undesired radiator spacing (Strahlerpitch).

In the design in question, it can furthermore be provided that the free ends of the wall sections of the channels are beveledIf the segments are joined to one another in the vertical direction, the free ends of the wall segments of the channels will come into contact and thus define an obliquely running gap through which no (or significantly less) radiation can pass than if the free ends of the channel segments were not chamfered, which would then form a gap aligned with the radiation.

As already mentioned, a connection region can be formed on the main reflector (or on a section thereof) on the rear side thereof, which connection region can be fastened to a corresponding part, which is associated therewith and is arranged on the side wall of the heating module. Preferably, the connection region has a dovetail shape and the counterpart is a snap made of spring steel.

Drawings

The invention shall be further elucidated hereinafter on the basis of a number of figures.

FIG. 1 shows a cross-section of an embodiment of a heating module;

FIG. 2 shows an embodiment of a reflector;

fig. 3a shows a section which can be obtained in the case of fig. 2 with the reflector divided along horizontal and vertical separation lines;

fig. 3b shows the section from fig. 3a with the inserted partial region of the heating radiator;

FIG. 4a shows a cross section of a partial region of a heating module, wherein the reflector is connected to the side walls of the heating module by means of a dovetail connection; and

fig. 4b shows a detail from fig. 4a, wherein the catch is offset in the bending region.

Detailed Description

Fig. 1 shows a cross section through a heating module 10, which heating module 10 has side walls 11, 12 and a bottom wall 13, which delimit a radiation space 14. In the region of the side wall 12, a plurality of tubular heating devices 15 are arranged one above the other in the vertical direction along the side wall 12. Between the heating devices 15 and the side wall 12, a main reflector 16 is arranged, in which main reflector 16 channels 17 separated by webs 60 are formed, which channels 17 accommodate the heating devices 15 and enclose a part of the circumference of the heating devices 15. The heating devices 15 and the channels 17 extend in the horizontal direction along the side walls of the heating modules 10 (or along the conveying direction of the heating channel formed by the heating modules).

Furthermore, a bottom reflector 18 covering the bottom wall 13 and a corresponding reflector 19 covering the side wall 11 are provided. The fixation of these reflectors is not shown in the figure. The fixing of these reflectors is effected in the usual way, for example by being held in a frame or by being inserted into a rail.

A plastic parison 20 is inserted into the heating module 10, the plastic parison 20 being held in the region of its neck 21 on an upper cover part 22 of the heating module 10, the lower region of the plastic parison 20 to be formed projecting into the radiation space 14.

Fig. 2 shows a perspective view of the main reflector 16 from fig. 1. It can be seen that these channels 17 extend through the main reflector 16 in the longitudinal direction. The reflector 16 may be fixed to the not shown side walls of the heating module by any means, such as by gluing or by a connection based on e.g. a slot/key, as will be discussed further below.

As described above, the manufacture of ceramic members becomes difficult with increasing size. In a further embodiment of the invention, it is therefore provided that the main reflector 16 is constructed from a plurality of segments. In fig. 2, vertical lines 23 and horizontal lines 24 are indicated, which are intended to illustrate the size and arrangement of the possible sections. It is thus possible, for example, for the reflector 16 to be assembled from a plurality of vertical subsections 25. The subsection 25 corresponds to that region of the reflector 16 up to the line 23. A plurality of such sections 25 are joined to one another in a horizontal direction to form the reflector 16.

Fig. 3a shows a section arranged along lines 23 and 24, namely: are delimited not only horizontally but also vertically. The section 26 shown here has an intermediate strip 27, from which intermediate strip 27 two wall sections 28 and 29 of the channel 17 extend. At that end of the section 26 which is directed toward the side wall of the heating module 10, a connecting region 30 is formed, which connecting region 30 enables the section 26 to be inserted into a corresponding rail which is fastened to the side wall, for example.

These segments 26 are arranged one above the other and next to the other, wherein two respective segments 26 arranged one above the other, together with their wall sections, form a complete channel profile. In order to avoid radiation losses in the intermediate region between the two vertically split sections 26, the free ends 30 and 31 of the wall sections 28 and 29 are beveled. In this way it is achieved that no or hardly any radiation will pass through the gaps between the sections 26. This is not the case in the case of non-chamfered wall regions: the gaps between the sections 26 are then directed perpendicularly to the side wall and aligned with the radiation of the heating tube.

Fig. 3b shows the section 26 with the heating radiator 150 arranged therein.

As mentioned above, another aspect of the invention relates to the fixing of the main reflector 16 to the side walls of the heating module 10. Fig. 4a shows a side wall 41 of the heating module 10, not shown in detail, in a partial section. A catch 42 is fastened to the side wall 41 by means of screws 43 and 44, which screws 43 and 44 are screwed into nuts 45, 46, respectively. Spacers 47, 48 are provided between the latching means 42 and the side wall 41, these spacers 47, 48 providing a thermal separation between the latching means 42 and the side wall 41 and furthermore serving to keep the latching means 42 free. Furthermore, the snap-in part 42 has nominal bending regions 49, 50, in which regions 49, 50 primarily an elastic deformation of the snap-in part 42 is achieved under force. These bending-rated regions 49, 50 are realized in the exemplary embodiment shown in this way: so that the catch 42 has a pre-bend set at the manufacturing side.

The catch 42 is configured such that the catch 42 can receive a connecting region 52 formed in the form of a dovetail on the main reflector 51. In the illustrated case, the latching means 42 are configured in such a way that a recess 53, 54 remains between the latching means 42 and the upper edge (or lower edge) of the dovetail 52. That is, the snaps 42 are longer than the dovetails. In these recesses 53, 54, the locking element 42 then does not rest against the dovetail 52, thereby ensuring that: a possibly larger-sized connecting region 52 within tolerance can also be accommodated in the snap-in piece 42 without problems.

Fig. 4b shows a detail of fig. 4 a. The only difference is that in the case of fig. 4b there is a connecting region 52', which connecting region 52' is slightly longer in vertical extension than in the case shown in fig. 4 a. As a result, the catch 42 is biased in the bending region 49 in the direction of the side wall 41 as a result of its pretensioning and rests with its free end (or limb) on the connecting region 52' over a slightly shorter distance than in fig. 4 a. In this case, however, the best possible surface contact between the catch and the connection region is ensured, so that a good fixing of the reflector is ensured.

In both embodiments of fig. 4a and 4b, it is provided that the catch is longer than the dovetail, i.e.: the region of the clip between its legs is longer than the path between the upper and lower edges of the dovetail. This dimensioning supports the bending properties of the catch.

It goes without saying that the bottom reflector and the counter reflector which are usually present in the heating module can also be fixed in the heating module, as can be the main reflector shown in fig. 4a and 4 b.