DE19923952A1 - Molding tool venting valve used in molds for rubber and similar materials and in particular in tire vulcanizing molds - Google Patents

Abstract

A first mechanism (S1) moves the closure piston (2) inside the body (1) and lifts the end face of the closing piston from the molding cavity surface to open the vent. When the venting valve is cold, a second mechanism (S2) moves the closure piston head onto its seat to close the vent and permit tool cleaning. During molding when the mold and venting valve are hot, the second mechanism opens the latter, closure being effected by material pressure in the mold cavity. Preferred Features: The first mechanism (S1) for valve opening in the hot condition is a compression spring which is longer in the hot condition than in the cold. A second compression spring (S2) closes the vent when the first compression spring is fully compressed. The venting unit body (1) is a tube and the valve seat between the body and closure piston (2) has complementary surfaces (4, 5) which contact when the vent is closed.

Description

The present invention relates to mold venting devices, those in the molding of vulcanizable rubber or other suchi formable materials are used, and in particular not only ventilation devices for tire molds.

When molding rubber items such as tires, this reduces catchy heating of the tire surface touching the hot mold, the Viscosity of the surface rubber, so that under the influence of A local flow of the rubber occurs. It is a Venting required to keep pockets of air between the pipe carcass and the hot mold surface can be enclosed, can escape, so that each part of the curing tire surface Touches shape and therefore the tire with a perfect impression of Shape details is vulcanized.

Bleeders for tire molds usually take that Form of small diameter holes that are perpendicular to the inside surface are drilled through the mold wall: The most common their vents so-called "emergency ventilation devices" ver turns, the tubes are with a small bore, due to the shape wall are introduced. As soon as all trapped air through the Hole is removed, the rubber begins to close through the vent hole flow. However, the small diameter of the hole ensures that the Rubber cures quickly, which closes the vent hole  and the mold is sealed. After curing is completed process, these rubber plugs are still on the tire surface hang out of the ventilation holes when molding the tire drawn.

Such stoppers made of rubber or "spue-pips" than that are commonly known for the appearance of the molded tire disadvantageous and are usually removed by cutting. This Clipping is time consuming and thereby increases the cost of the Tire manufacturing.

A problem can also arise if the cured buds breaks off when the tire is removed and therefore remains behind and that Vent hole clogged. Such a clogged ventilation device is not immediately recognizable and can use the following molded parts cause poor quality.

In order to solve the above-mentioned problems, so-called "drive-free ones Venting devices "have been proposed that allow trapped air can escape, but close to ei to prevent a rubber flow.

US 4,492,554 and US 4,347,212 disclose examples of such "Drainless" ventilation devices. This known vent directions include a valve that is normally operated by a screw spring is kept open to allow the passage of air. The Ven til is closed by flowing rubber that seals a valve head  cut into a seated engagement against the spring tension Valve seat moves.

However, there is a problem with known venting devices when molds containing them are cleaned. A regular one Mold cleaning is necessary to remove material deposits conditions that are baked on the mold surfaces, creating a good Appearance of the surface of the molded article is ensured. Cleaning is usually done by using the mold surface a low-abrasion material, such as plastic sand, sandge shines. Such sand can be dry or wet in one Water flow can be used. Because conventional ventilation equipment If cleaning is open during the cleaning process, the Reini medium and removed dirt into the ventilation devices penetrate and clog them. Such blockages are only frequent Obviously, if the shape is poor at the onset of an appearance Molded parts are returned for maintenance.

Accordingly, it is an object of the present invention to make one fanless vent to create the above described Prevents clogging problem while cleaning the mold.

According to the invention, a venting device for a mold comprises the has a mold cavity, a main body, a closing element, which is moved by a first means to move with respect to effect the main body and thus the venting device too open, and which has an upper end surface arranged in such a way that with the vent closed, at or near the  Surface of the mold cavity is arranged, and a second means that is set up in such a way that when it is cold, the ventilation device tion closes so that in use when the shape and the vent device are hot, the venting device from the second means can be opened and of material in the mold cavity that the touches the upper end surface of the closing element, can be closed, and it is closed when cold to clean the mold allow.

Therefore, according to the invention, the valve is open when the mold is heated and it is subsequently affected by the action of the on the upper end surface impacting, shaped object closed, but that is Valve closed when the mold has cooled down, as is the condition of the Is cleaning.

With a venting device when hot it is meant that the Venting device essentially the forming temperature of the Ge object, and when cold it means that their tempe temperature is significantly below the molding temperature. In the case of a Rei fens, the molding temperature can be, for example, 180 ° C.

The first means may comprise a leaf spring which acts to the venting device opens depending on its temperature closes as well, or it may include separate spring means one to open the venting device and another to Closing the venting device.  

Such a spring means comprises a metallic, so-called "Formge memory alloy "or" SMA (shape memory alloy) ", in which the Fe which is created by changing its shape in response to the tem temperature is changed. Typical shape memory alloys of this type can a change in shape in the temperature range between 90 ° -120 ° er drive and are therefore well suited to between a shape in reverse temperature and another shape in the tire molding temperature temperature of 180 ° C or toggle back and forth.

The venting device is preferably made of a moldable art fabric material formed.

The invention will be exemplified below with reference to the drawing wrote, in this shows or show

Fig. 1 is a partial sectional view of a vent insert according to an embodiment of the invention,

FIG. 2 shows a further sectional view of the insert ventilation device from FIG. 1, which is taken along the plane AA ′, FIG.

Fig. 3 is another sectional view of the use of venting means of FIG. 1,

FIGS. 4A-4B show further embodiments of the invention,

Fig. 5 is a vent insert device according to the invention, which is put in its place in the sidewall region of a tire mold,

Fig. 6A-6C show further embodiments of the invention, and

Fig. 7 shows another embodiment of the invention.

In FIGS. 1-3, a form of venting means in accordance of one embodiment of the present invention is shown. In use, the ventilation device is arranged in the mold wall, one end surface 3 being on the mold surface and the opposite end surface 6 being open to the atmosphere, and providing a closable air outlet passage between the two end surfaces.

The main elements of the ventilation device comprise a main body 1 , a closing element 2 , which is arranged displaceably within the main body, and a first and a second spring means S1 or S2, for moving the closing element 2 with respect to the main body, in order to close the ventilation device open and close.

The main body 1 is generally a tubular structure that is open at both ends to provide an air outlet passage through the interior of the main body. Inside a part of the same, a constricted section 6 is provided, which coaxially arranges the closing element 2 and leads its movements. At the upper end 3 of the main body 1 , which is the end which is arranged on the upper surface, there is an inner, conical seat 4th A complementary, outer, conically shaped closing surface 5 is provided at the upper end of the closing element 2 . The valve closes when the complementarily conically shaped surfaces of the closing surface 5 and the seat 4 are brought together by a movement of the closing element 2 within the main body 1 downwards.

In an open state, which is shown in FIG. 1, there is an air outlet passage from the upper end face 3 between the complementary conical surfaces 4 and 5 through the inner, constricted section 6 , via slots 7 s, which are shown in FIG. 2 are shown in section, and from there on the remaining inner tube section 7 is provided.

In a closed state, which is shown in Fig. 3, the air outlet passage is closed by the coming together of the complementary ko African surfaces 4 and 5 in a seated engagement by the movement of the closing element 2 within the main body 1 , which results from that molded material strikes the end face of the closing element 8 and presses against it.

Now the role of the spring means S1 and S2 in the operation of the vent establishment explained.

The first spring means S1 10 of the inner, the constricted portion 6 is disposed between an inner surface 9 of the Schließele component 2 and the adjacent surface of the main body 1, and serves to bias the closure member 2 of the main body 1 in the direction indicated by arrow O toward the outside to open the venting device.

The second spring means S2 is arranged between a securing bracket or ring 11 , which is fastened to the lower part of the closing element 2 , and the adjoining other surface 12 of the inner, constricted section 6 and serves to close the closing element 2 with only minimal force pre-tension inside the main body 2 in the direction indicated by arrow C to close the venting device. The provision of the locking ring 11 is necessary so that the closing element 2 can initially be installed in the main body 1 , after which the second spring means S2 and the locking ring 11 are attached to the lower part of the closing element 2 as shown. The safety bracket 11 is arranged with a loose sliding seat within the tubular lower section, so that a passage of escaping air is possible.

The first spring means S1 comprises a shape memory alloy. Such Materials have the property that they have a special shape can be brought and then plastically from this target shape. can be deformed. However, if you have a critical or Switching temperature are heated, they become their target shape to return.

In this particular embodiment, the spring means S1 comprises such a shape memory alloy, the critical temperature of which is in the range of 80 ° -120 ° C. This material, which is in the form of a wire, is shaped and placed in a helical, open-wound spring, the first length l1 of which corresponds to the distance between the surfaces 9 and 10 when the valve is in the open position, as shown in FIG . 1 is shown.

When the venting device is in operation when molding a rubber tire, trapped air escapes through the open venting device until the rubber or rubber hits the end face 8 of the closing element and pushes the closing member 2 into the main body 1 , so that the conical surfaces 4 and 5 fit into a seated position Be engaged to thereby close the air outlet passage between them. The action of the flowing rubber, which closes the venting device, compresses and deforms the first spring means S1 to a shorter second length l2, as shown in FIG. 3.

After the molding and vulcanization is complete, the Arranged below the critical temperature of the shape memory alloy cooled and the tire is molded. After the tire has been removed, the ventilation device remains due to the plasti deformation of the first spring means S1 and the preload Kung the second spring means S2, which has a minimal spring force ready provides that is only sufficient to halve the ventilation device ten, in the closed state.

However, during reheating in preparation for the next molding cycle, the first spring means S1 switches back to its original target state as soon as the mold temperature reaches the critical temperature of the shape memory alloy, and thus the compressed helical coil expands from its length l2 to its original Target length l1, the closing element 2 being moved against the minimal spring force of S2 from the main body 1 to the outside, so that the ventilation device is opened in readiness for the new molding cycle.

That is why this new venting device will be in operation as soon as the Venting device is closed, remain closed until it is on the critical or switching temperature of the shape memory alloy of the he most spring means is heated. Accordingly, after completion the desired number of molded parts for maintenance be removed and cleaned while the venting device is in operation remain closed.

In a variant of the above embodiment, the first spring takes medium S1 has a different shape. In this variant switches or changes the spring from the shape memory alloy in response single temperature between a longer first length and a short one zer second length. As a result, the spring has one when hot first length l1, and in the cold state the spring pulls short ren length l3 together, the same or preferably slightly smaller than the length l2 which is the closed state of the vent represents direction. Thus, the function of the second spring means S1 le diglich to record the movement or free play of the closing element when the venting device is closed. Hence the Venting device in this variant in response to temperature both open and closed, and it is therefore not necessary that it is cooled with the molded article in situ to remove the ent ventilation device in the cold state in the closed state convict.  

In a further variant of the above variant, the respective Ends of the first spring means S1 firmly on the main body or Closing element may be attached so that the spring means S1 the closing element not only to open the ventilation device but also moved to close the same, eliminating the need for that second spring means S2 is avoided.

While in the above-described embodiments of two Forming a shape memory alloy using the spring means has been made, other designs of a spring can be made from a Shape memory alloy, such as membranes or spring fingers, or shapes can be used from a spring-actuated spring means. For example, it is possible to use a bimetal spring means or another to use such spring means.

Other embodiments shown in FIGS. 4-6 illustrate examples of alternative spring means.

In Fig. 4, a further embodiment of the present invention is shown ge, in which the spring means for actuating the closing element 21 takes the form of integrally formed struts 23 . According to the sectional diagram 4 A of the ventilation device in the open position, these legs 23 are arranged in an inner groove 25 or grooves, which are provided in the wall of the inner hole 27 in the main body 22 . Fig. 4B is a sectional view taken in the plane AA 'of Fig. 4A and shows three such struts 23 equally spaced and separated from one another inside the main body 22 to allow passages 26 for the air flow out of the mold to provide. These struts each comprise a conventional bimetal structure with different thermal expansion properties. In the cold or cool state, the struts are designed such that they bias the device 21 inward into the main body 22 so that the shape is closed, as shown in FIG. 4B. When the ventilation device is heated, the different expansion of the struts 23 causes the closing element 21 to be biased outwards, so that the ventilation device is opened, as shown in FIG. 4A. If rubber or rubber presses on the closing element 21 , who the spring struts deformed against the biasing force of the bimetallic expansion, so that the venting device is closed again, as shown in Fig. 4B. When cooling and removing the hardened tire from the mold, the struts 23 remain in such a way that the ventilation device is kept closed until it is heated again.

While the struts in the second embodiment are shown and described such that they are arranged in the inner grooves 25 of the inner wall of the main body, they can also be formed in one piece with the main body 22 . Such an arrangement is shown in FIGS . 6A-6C, wherein temperature-actuatable spring means 63 , which function as described above, are formed integrally with the main body and are arranged in an annular groove 69 at the lower section of the closing element.

In alternative embodiments, the struts can by a complete spring washer must be replaced.  

In the above-described embodiments, the upper end 3 of the main body and the end surface 8 of the closing element 2 form a flat surface when the ventilation device is closed.

In an alternative embodiment shown in Fig. 7, the upper end 3 of the main body is provided with an annular raised portion 70 which in this particular embodiment forms a half torus. This raised portion is useful for providing a surface for pressing or wrapping when the vent is fitted into the mold and can then be removed to allow the top surface of the vent to be flush with the mold surface.

Claims (8)

1. Venting device for a mold that has a mold cavity comprises a main body, a closing element, the is moved by a first means to relate to a movement effect on the main body and thus the ventilation direction to open, and which has an upper end surface that the is set up so that it is closed venting device tion located at or near the surface of the mold cavity is net, and a second means, which is set up in such a way that cold condition closes the venting device, so that in Ge need when the mold and vent are hot, the venting device can be opened by the second means can and of material in the mold cavity that the upper end Touched surface of the closing element, can be closed, and it is closed when cold to clean the mold too allow. 2. venting device according to claim 1, characterized, that the first means of opening the valve when hot is a Preload spring made of a shape memory metal alloy (SMA) sums up.   3. venting device according to claim 2, characterized, that the bias spring in the hot state longer than in the cold closed stand is. 4. venting device according to claim 3, which includes a closing spring to ver the venting device close when the preload spring takes on its shorter length. 5. venting device according to claim 1, characterized, that the first means a bimetallic Includes spring means. 6. venting device according to one of claims 1 to 5, characterized, that the main body comprises a tubular body, and that the closing element is arranged inside the tubular body is. 7. venting device according to one of claims 1 to 6, characterized, that the valve seat between the main body and the closing element includes complementarily shaped surfaces that at ge with the ventilation device closed while seated.   8. venting device according to claim 7, characterized, that the complementarily shaped surfaces of the main body and the closing element are conical surfaces.