LT4520B - A valve assembly for venting diecasting moulds - Google Patents

Abstract

The valve joint for die-cast form ventilation consists of outlet channel tools, an outlet valve, which connects to the outlet channel and has in the axial direction a moving valve closing element and starting element for changing outlet valve control from opening into closing position. The starting element comprises a power absorption element, which is affected during the moulding process by liquid moulding material, that flows out of the cast moulding chamber through the mentioned channel. Moreover, it is moved in the axial direction by the effect of kinetic power carried by the liquid moulding material to the power absorption element, when the liquid moulding material hits the power absorption element. The power absorption element is mechanically connected to the valve closing element, that moves in axial direction, and includes moving in the axial direction a piston element with working stroke, the length of which is limited only to part of the working stroke length, performed by the valve closing element, when it moves from opened to closed position, moving in axial direction. The valve closing element, which moves in axial direction, moves freely along the trajectory beside the before mentioned power element working stroke. Also, in order to convey to the outlet valve closing element, which moves in axial direction, the dynamic power by the liquid moulding material given to the power absorption element, the starting element includes a power carrying element.

Description

The present invention relates to the casting pressure of a valve assembly for venting molds. The valve assembly comprises an outlet, an outlet valve communicating with the outlet, and having an axially displaceable valve closure member, and an actuator for controlling the outlet valve from an open position to a closed position.

The actuator includes an energy absorbing member actuated by a liquid molding material that escapes during discharge from a discharge chamber in an injection molding die and axially displaced by the kinetic energy transmitted to the liquid molding material energy absorption member when the liquid molding material encounters energy absorption. element. The energy absorbing member is mechanically coupled to the axially displaceable valve closure member and has an axially displaceable pusher.

Valve assemblies of this type are usually mounted on one of two sides of a die casting mold; when the mold in its initial position is ready for casting operation, said two sides are in contact with each other along a dividing plane. In general, the design is such that one side of the mold has a notch at the periphery, and the valve assembly is mounted in this notch so that its front face does not protrude above the above dividing plane; such that when both sides of the form are joined, i.e. when the injection mold is closed, the front face of the valve assembly is hermetically pressed against the front face of the other side of the mold. The outlet of the valve assembly is open to the side of the above-mentioned front surface and forms a die-cast integral discharge channel which is also open to the side of the front surface.

The end of the outlet of the valve assembly leading to the atmosphere is either open or connected to a vacuum suction means. Vacuum suction means serve to remove the air contained in the mold casting chamber when the liquid casting material is poured into the mold at high pressure and high speed.

An outlet valve assembly that closes as soon as the venting process is completed to prevent liquid molding material from escaping from the mold or into a vacuum pump connected to an outlet. The closing of the valve assembly is initiated by the flow of liquid molding material into the outlet of the valve assembly. For this purpose, according to the state of the art, the impact or dynamic pressure exerted on the inside of the valve assembly as the liquid casting material flows into the mold is used to close the discharge valve. Given that the liquid casting material flows into the mold at very high pressure and, after filling the mold casting chamber, flows at the same high pressure and speed into the outlet of the valve assembly toward the discharge valve, the operation of the discharge valve must begin very quickly to secure the valve assembly. closing until the liquid casting material reaches the drain valve. It is extremely important to prevent liquid molding material from penetrating inside the drain valve, otherwise the drain valve will be blocked.

Practice has shown that such valve assemblies can execute the discharge valve operation in an extremely short time (i.e., less than 1 msec), provided that appropriate means are provided to convert the above dynamic action or impact pressure to the actuation force of the discharge valve; this can ensure the reliable operation of such a drain valve.

Swiss patent no. 633 208 discloses a drain valve assembly of the above type which is intended for use in connection with high pressure injection molding operations and which operates quite well. In fact, this valve assembly has a plunger valve member having a central axis perpendicular to the front face of the valve assembly, comprising a valve cylinder communicating with the vent passage and a valve piston moving within the valve cylinder. The valve piston has a bottom of a piston that protrudes at the front of the valve assembly into the outlet when the valve assembly is open, and which is located inside the valve cylinder when the valve assembly is closed.

In addition, an actuator assembly is provided comprising an energy absorbing member in the form of a piston-cylinder device, the control cylinder of which communicates with a portion of the outlet channel located upstream of the valve cylinder, viewed in the direction of flow of the liquid molding material. The control cylinder has a piston member that is exposed to a liquid molding material flowing into the outlet. The actuator control cylinder and plunger valve cylinder are disposed on parallel axes, and the actuator piston is connected to the valve piston such that the actuator piston, when exposed to liquid molding material and accelerates its retraction, acts on the valve piston in the discharge direction.

In the construction according to the aforementioned Swiss patent no. The piston of actuator assembly 633 208 is connected to the valve piston either directly or through a guide member, and such member moves parallel to the path of movement of the valve piston. In this embodiment, the actuator piston is connected to the actuator in a non-assembled manner. However, in any case, the trajectory along which the actuator piston moves is the same as the valve piston trajectory; in practice the length of this trajectory is 5 - 10 mm. This circumstance proved dangerous in several respects.

After dynamic or impact action of the liquid molding material, the moving mass (i.e., the actuator piston, guide, and valve piston) of the actuator piston has a relatively high kinetic energy at the end of the trajectory, which must be absorbed at the end of the motion trajectory. A rigid support could probably cause the entire valve assembly to fail. This requires the provision of appropriate shock absorbers, but this will be costly, especially if the time or trajectory at which the mass velocity is to be reduced is relatively short. With this in mind, it should be noted that the discharge valve plunger has a well-defined trajectory to the point where it is in a predetermined closed position. If this trajectory is prolonged during the deceleration process, even if within a very short period of time, liquid molding material can penetrate the valve cylinder, resulting in a major disruption or even impossibility of discharge valve operation.

On the other hand, during actuation of the actuator piston, the cylindrical portion of the actuator cylinder is exposed to liquid molding material. This freely acting part of the cylindrical wall is the same length as the piston stroke. In this way, the liquid molding material which penetrates the actuator cylinder forms, after curing, a plug which can be pushed into the actuator cylinder. Due to its length, its removal from the cylinder passage is difficult and requires great force. As a result, both sides of the mold are difficult to open and the actuator cylinder can be damaged. In any case, attention must be paid to the rapid wear of the cylinder channel surface, especially if the liquid molding material is of aggressive origin.

It is an object of the present invention to provide a valve assembly for injection molds which does not have the disadvantages mentioned herein.

More particularly, it is an object of the present invention to provide a valve assembly for injection molding molds in which the kinetic energy to be absorbed by the energy absorbing member is reduced to a level sufficient to initiate closure of the discharge valve.

In accordance with these and other objects, the present invention provides a valve assembly for venting molds, comprising an outlet, an outlet valve communicating with the outlet, and having a valve closure member movable in an axial direction.

Actuators are provided for controlling the drain valve from the open position to the closed position, and these actuators include an energy absorbing member actuated by the liquid molding material that escapes during discharge from the molding chamber in the mold. It is displaced axially by the kinetic energy transmitted from the liquid molding material to the energy absorbing member when the liquid molding material strikes the energy absorbing member.

The energy absorbing member is mechanically coupled to the axially movable valve closure member and has an axially movable pusher with a stroke whose length is limited only to a portion of the stroke length of the axially movable valve closure member when moving from the open position to the closed position. position.

In addition to the aforesaid operation of the energy absorbing member, the axially movable valve closure member is adapted to move freely in an additional trajectory. Finally, the actuator further comprises energy transfer means for transmitting the dynamic force exerted by the liquid molding material on the energy absorbing member relative to the closing member of the axially movable discharge valve.

According to such a design, the kinetic energy of the energy absorbing element can be kept within acceptable limits due to its short workflow, and can be absorbed without risk even with rigid selection, without the use of expensive shock absorbers. The shut-off element of the drain valve, free from collisions or shocks acting on the energy absorption element, moves freely until it reaches the closed position. Thanks to free movement, i.e. the fact that the free connection of the energy absorbing member and the closure member is released after the liquid molding material strikes the free front face of the energy absorbing member ensures that the main part of the movement path of the energy absorbing member can be used to reduce and absorb the material kinetic energy. Thus, the required velocity reduction means may be much simpler than prior art impact absorbers for the entire assembly, which can only reduce velocity at the end of the valve closure workflow. The time required to close the drain valve is not increased and is about 1 msec.

As proposed in the preferred embodiment, when the energy absorbing member is in the form of a free-floating piston that moves in the cylinder communicating with the outlet valve assembly channel, the exposed portion of the liquid molding material in the cylinder wall is very small due to short free-floating piston travel. In this way, the hardened plug of the float piston on the front is very short and can be easily pushed out by opening the two sides of the mold.

Due to the fact that the energy absorbing element has only a very short run, the diaphragm can be used as an energy absorbing element; preferably, this diaphragm covers the outlet of the valve assembly outlet. In this way, all possible disadvantages of the piston exposed to the liquid molding material are avoided.

As mentioned above, the operating conditions require that the actuator assembly energy absorbing element and the drain valve be located at different locations in the valve assembly outlet duct. Thus, the direct transfer of energy between the energy absorption element and the movable part of the drain valve cannot be realized. Because of this fact, in an optimum embodiment, the valve assembly may comprise a guide plate member that may move axially and coaxially disposed relative to the energy absorbing member; the portion of the outer edge of the guide plate member being prefabricated with the drain valve plunger and the guide plate member lying in front of the energy absorbing member when the spring member is in the idle position.

The above actuators may further comprise a actuator which is operably coupled to the discharge valve axially movable closure to hold the valve closure in the closed position in which it is exposed by the energy absorption element of the liquid molding material.

In order to reduce the mechanical wear of the parts included in the operation of the drain valve, the energy transfer member is loosely coupled to the axially movable pusher and assembled to the axially movable valve of the discharge valve.

The drain valve may comprise a piston valve member with a plunger, wherein the energy absorbing member is disposed in a parallel axis relative to the plunger.

There are different solutions for practical use of energy transfer means: they may include a baffle element which is axially movable and coaxial with respect to the energy absorbing element, a portion of the outer edge of the baffle element is prefabricated with the discharge valve plunger, and an element acting on a spring element when the valve assembly is in the non-operating position. Another possibility is that the power transmission means consists of a pivot lever, prefabricated with a discharge valve plunger, the pivot lever lying in front of the energy absorbing member, the spring member being actuated when the valve assembly is in the inactive position.

In the preferred embodiment, the actuator is comprised of a control cylinder with a pneumatic or hydraulically actuated piston, the actuated piston being prefabricated with an axially movable shut-off valve of the discharge valve by means of a rigid intermediate coupling member.

The control cylinder of the axially movable closure member may be provided with an inlet nozzle member having a nozzle channel projecting forwardly into the interior of the control cylinder. The nozzle channel is secured to the front face of the actuator control piston, and the spring member is provided inside the control cylinder to press the control piston against the nozzle channel.

To ensure reliable operation of the actuator assembly, keeping the outlet valve closed, hydraulic or pneumatic pressure for actuator control, ratio between nozzle channel cross section and control cylinder clamping nozzle channel, front surface transverse section and spring member pressing on control piston, the technical characteristics are selected such that when the control valve member is closed, the pressure of the hydraulic or pneumatic medium on the inlet nozzle and the operating surface of the control piston is not sufficient to open the control valve member; but when the control valve member is mechanically open, the pressure of the hydraulic and pneumatic media now acting on the entire front surface area of the control piston is sufficient to allow the control piston to close and keep the drain valve means closed.

It has been proven useful that the stroke member stroke is approximately one tenth of the stroke of the axially movable valve closure member when moved from the open position to the closed position, preferably less than 1 mm and more preferably about 0.1 mm.

Several embodiments of the valve assembly according to the invention will be further described with reference to the accompanying drawings, in which:

FIG. 1 is a longitudinal sectional view of a first embodiment of a valve assembly mounted in one portion in the shape of a two-piece shown in an open configuration;

FIG. 2 shows a valve assembly according to FIG. 1 front view of first part of housing;

FIG. 3 shows a valve assembly according to FIG. 1 view from above of the first part of the housing;

FIG. 4 is a view showing the housing housing the front valve assembly of FIG. Part 1, front view of another part;

FIG. 5 shows a valve assembly according to FIG. 1 longitudinal view with the mold closed and the valve assembly open;

FIG. 6 is a similar view to that of FIG. 5, when the valve assembly is closed;

FIG. 7 is a longitudinal sectional view of a valve assembly according to a second embodiment of the present invention;

FIG. 8 shows a variant of FIG. 7, fragment; and

FIG. 9 shows an embodiment of the embodiment shown in FIG. 7, fragment, but modified according to a third embodiment of the valve assembly.

The valve assembly 1 shown in Figs. 1-6, is housed in a rectangular parallelepiped two-piece housing having a rear housing portion 2 and a front housing portion 3 with a flat front surface 5. In other words, the valve assembly 1 housing is divided along a dividing plane 4 into two portions 2 and 3. portions 2, 3 are arranged in a notch 6 on the mold side, and the two sides 6 and 7 of the mold are adapted to be compressed with one another as known in the art. The valve assembly 1 is positioned at the outer edge of the contact surface 8 of the mold side 6. Shape sides 6 and 7 are partially shown in the drawings. The front surface 5 of the housing parts 2, 3 coincides with the contact surface 8 of the mold side 6 such that the front surface 5, like the contact surface 8, is hermetically joined to the contact surface 9 of the other side 7 of the mold when the mold 6, 7 is closed.

Body parts 2, 3 may be fastened to the mold side by means of clamping means not shown in the drawings. Similarly, body parts 2 and 3 may be secured to each other by means of clamping means not shown in the drawings.

The casing part 3 has a discharge channel, generally designated 10; this outlet duct 10 is open to the front surface 5 of the body portion 3. This outlet 10 of the valve assembly 1 will be described in more detail in connection with FIG. 4 later. The outlet channel 10 communicating with the mold casting chamber is a continuation of the outlet channel 11 provided on the mold side 6 and open also to the contact surface 8.

The drain valve 12 of the valve assembly 1 is constructed as a plunger valve which is described, for example, in Swiss patent no. 633 208 in description. Its longitudinal axis is perpendicular to the front surface 5 of the housing parts 2, 3. The drain valve 12 has a valve cylinder 13 communicating with the drain channel 10 as well as a valve piston 14 moving along the cylinder 13. The valve piston 14 has a piston bottom * 15. to the outlet duct 10 from the front side of the valve assembly 1 if the drain valve 12 is open (as shown in Figs. 1 and 5). In order to close the drain valve 12, the piston bottom 15 is axially displaced to the inside of the valve cylinder 13 (as shown in Fig. 6). At the top of the housing part 3 there is provided an outlet channel 16 for a drain valve 12; a vacuum pump suction tube (not shown) is connected to this outlet channel 16. The chamber 18 disposed behind the rear cylindrical extension member 17 of the valve piston 14 communicates with the conduit 19 in the housing portion 2 which is discharged into the atmosphere; in this way, for example, gauges can be connected to the channel 19 to control the correct operation of the valve assembly 1.

In order to close the discharge valve 12, a control unit consisting of several different elements is provided. The main part of this assembly is a movable energy absorbing means which is exposed to a molding material flowing from the injection chamber into a mold through a discharge passage 11 to a discharge passage 10. The energy absorbing means mentioned above are mechanically coupled to a piston 14 of a discharge valve 12. the means being in the form of a pusher mounted slidably along the short stroke and, in this example, constructed as a floating piston 20 movably disposed within the control cylinder 21 communicating with the outlet duct 10. The longitudinal axis of the control cylinder 21 is parallel to the longitudinal axis of the drain valve 12. The floating piston 20 has a rear cylindrical extension member 22 extending almost to the rear wall 23 of the housing part 2. If the liquid molding material still enters the outlet 11 and presses the floating piston 20, the latter is pushed until the extension member 22 rests against the rear wall 22 23. Thus, the stroke of the floating piston 20 is limited to an amount which is only a part of the closing stroke of the valve piston 14, e.g.

The impulse impulse is transmitted from the floating piston 20 to the piston 14 of the discharge valve 12 in the form of an energy transfer guide plate 24. The guide plate 24 is mounted on a coaxial floating piston 20 and slidably secured by a hub member 25 to the cylindrical extension member 22. The axial travel of the guide plate 24 is limited on one side by the shoulder 26 of the housing portion 3 to the separating plane 4 on the other. in the housing part 2. The floating piston 20 has a ring 28 which is located in the center of the guide plate 24 to freely lock the latter during the movement of the floating piston 20. The guide plate 24 engages with a groove in the valve piston 14 at its circumferential location 29 and is thus removably coupled to the valve piston 14.

To return the valve assembly 1 to its original position, as shown in FIG. 1, i.e. at the end of the molding operation, a spring assembly 30 is provided comprising a spring package 31 comprising a plurality of disc press springs. The spring package 31 is disposed between the stationary pressure plate 32 and the movable pressure plate 33 in the housing part 2 inside the drilled channel 34. The movable pressure plate 33 is provided with a sleeve-shaped extension member 35 which freely encloses the hub member 25 of the guide plate 24 and, internally, the springs of the spring package 31. In order to compress the spring package 31, there are two push rods 36 and 37 which slide in respective drilled passages in the housing part 3 and the guide plate 24 and which are supported by the movable pressure plate 33 of the spring assembly 30. 3 and is pushed to the inside of the valve assembly 1 by a contacting surface 9 when the mold is closed by joining the two mold sides 6 and 7; in this way the spring assembly 30 (Fig. 5) is compressed.

It should be noted that for clarity both rods 36 and 37 shown in Figs. 1, 5 and 6, are in the general vertical plan; but in practice they are arranged in a general horizontal plan, as can be seen from Figs. 4 to simplify the shape and construction of the outlet channel 10.

The aforesaid control unit may further comprise a actuator 38 operatively coupled to the piston 14 of the drain valve 12 to maintain said valve piston 14 closed when introduced into said closed position by an impact pulse transmitted by the floating piston 20. As noted above, actuator 38 is not required but may be useful in many applications of the valve assembly of the present invention.

In this example, the actuator 38 comprises a control cylinder 39 with a pneumatically or hydraulically actuated controlled piston 40, both disposed on a parallel axis relative to the drain valve 12. The control piston 40 is removably coupled to the guide plate 24 in the same manner as the valve piston 14; namely, the guide plate 24 at the circumferential location 41 opposite the location 29 connected to the groove in the control piston 40. Thus, the control piston 40 of the actuator 38 and the piston 14 of the drain valve 12 are assembled by a guide plate 24 to form a rigid connection .

The actuator piston 40 of the actuator 38 is actuated by a spring element 42 which, when pressed by the spring assembly 30, presses the guide plate 24 against the ring 28 of the floating piston 20 and at the same time holds the piston 14 of the drain valve 12 in the open position. A pneumatic or hydraulic stroke on the control piston 40 is typically accomplished by means of a valve actuator controlled by a piston 14 of the discharge valve 12. Due to the rigid connection of the discharge valve 12 piston 14 to the actuator piston 40, it is advantageous to provide a disc valve valve actuator, then actuator piston 40 of actuator 38 serves as the bottom of the valve. In this sense, an actuator nozzle 43 disposed in the actuator cylinder 39 of the actuator 38 protrudes in front of the cylinder chamber, the actuator cylinder 40 clamping the nozzle opening 44 on its front surface when the spring 42 is actuated. 3) through an inlet 45 (Fig. 2, 3) through channels 46, 47 and 48 provided inside housing part 2 and through channels 49, 50 and 51 provided inside housing body 3.

The pressure of the hydraulic or pneumatic medium for actuating the actuator 38, the relationship between the free cross-sectional area of the inlet nozzle 43 and the cross-sectional area of the control cylinder 39 and the spring 42 acting on the control cylinder 40 are selected such that the control valve 40, 43 is closed. the pressure of the hydraulic or pneumatic medium at the inlet nozzle 43 and the impact on the front surface of the control piston 40 is insufficient to open the winding ..a., .. 40. 43, without. · "Ο the throttle is such that the above pressure is sufficient when the control valve is open mechanically, to enable the control piston 40 to close the drain valve 12 and hold it closed by the pressure exerting on the entire front surface of the control valve 40.

The outlet 10 of the valve assembly 1 comprises a plurality of channel branches 52-59 and chambers 60-62, all of which collectively serve, as is well known, for collecting the splashes accompanying the continuous flow of liquid molding material, raising the impact pressure exerting pressure on the floating piston 20. from the collection chamber 60 disposed at the inlet of the outlet duct 10, two duct branches 52 and 53 lead to an extension 63 located in the area in front of the pusher control cylinder 21. From this extension 63 the other two duct branches 54 and 55 each lead to retention chambers 61 and 62. Further, the channel branches 56, 58 and 57, 59 respectively lead to a further extension 64 located in the area ahead of the drain valve 12.

FIG. 5 shows the valve assembly 1 in its initial position. The form of snooze casting is closed i.e. the mold side 7 is in printed contact with its contact surface 9 with the contact surface 8 of the mold side 6 and the front surface 5 of the valve assembly 1. The mold is closed so that the spring assembly 30 is compressed by the push rods 36 and 37. The drain valve is still open As a result of the action of the spring 42 of the element 38, the air pushed out of the casting chamber can penetrate in the direction of the arrows 65 and 66 through the discharge duct 11 of the injection mold, the outlet 10 of the valve assembly 1 and the outlet 16. 40, 43 is still closed.

At the end of the casting operation, the liquid casting material escaping from the die casting chamber through its outlet conduit 11 penetrates the outlet conduit 11 of the valve assembly 1 and flows through the duct branches 52, 53 (Fig. 4) to the floating piston 20 of the actuation assembly. by pushing the front surface of the floating piston 20 with a strong impact, the floating piston 20 is pushed abruptly towards the rear wall 23 of the braking member 23 of the extension member 22 on the floating piston 20 and transmits this stroke to 20, is disengaged from the ring 28 of the free-floating piston 20 as soon as the piston reaches its end position. The guide plate 24, together with the piston 14 of the drain valve 12 and the control piston 40 of the actuator 38, is then further pushed against the force of the spring 42 of the actuator 38. In this way, the drain valve 12 is inserted. The radial piston 14 is pushed inside the valve cylinder 13. the closing movement of the release valve Ϊ2 is controlled by the actuator piston 40 of the actuator 38, since the front surface of the actuator piston 40, when pushed into the floating piston 20, is exposed to all of the pressure medium filling the cylinder chamber 39 through the nozzle 43. In the closing direction (to the left of Fig. 1), it is conveyed by the guide plate 24 to the drain valve piston 14.

FIG. 6 illustrates the situation of valve assembly 1, in which liquid molding 67 flowing from the mold molding chamber through outlet duct 10 has reached an expansion 63 at the floating piston and immediately thereafter (e.g. less than 1 msec) an extension 64 at the outlet valve 12 piston 14. During this short period of time, viz prior to the liquid molding material also reaching the expansion 64 at the valve piston 14, the drain valve 12 is already closed, such that the valve piston 14 has reached its end closed position in the manner described above. This ensures that the liquid casting material flowing through channels 56 - 59 to the expansion 64 cannot enter the interior of the drain valve 12 and the exit channel 16. The end of the actuator displacement trajectory is reached as soon as the guide plate 24 hits the movable pressure plate of the compressed spring assembly 30. 33.

By means of the actuating cylinder 40 of the actuator 38, which is still pressed, the piston 14 of the drain valve 12 is kept closed with the aid of a guide plate 24. As can be seen in FIG. 6, the liquid molding material 67 can penetrate only very limitedly into the cylinder 21 of the floating piston 20 and, after a short period of time, into the cylinder 13 of the drain valve 12; logically, the removal of the liquid molding material from the discharge channel 10 is not a problem.

When opening a die casting mold, i.e. separating the two mold halves 6 and 7 from one another, the spring assembly is released because the two push rods 36 and 37 are no longer locked on the contact surface 9 of the mold half 7 in their previous positions. In this manner, the spring assembly 30 pushes the guide plate 24 and simultaneously the piston 14 of the release valve 12, as well as the control piston 40 of the actuator 38, and finally the floating piston 20 back to their original positions by the spring assembly 30. 1. At the same time, the bottom 15 of the valve piston 14 and the front surface of the floating piston 20 displace the cured molded parts from the extensions 63 and 64, resulting in the removal of all cured molded material from the drain channel 10. In addition, the control valve 40,43 for actuator 38 The run is a cancerous closure.

FIG. 7 and 8 show a slightly different scale view of a valve assembly of a slightly different construction according to the invention. The valve assembly 71 according to FIG. 7 and 8 are also housed in a rectangular parallelepiped housing 72, 73. Said housing is divided along a dividing plane 74 into a posterior portion 72 and a front housing 73 having a flat front surface 75. In a manner similar to that described with respect to the embodiment of FIG. 1 to 6, the valve assembly 71 may be attached to a multi-part injection mold (not shown).

Like the discharge valve 72, this embodiment similarly consists of a piston valve having a valve cylinder 78 communicating with the exhaust channel 79 and connected to the discharge channel 77, and an axially sliding plunger 80 having a plunger bottom 81. As a pushing element, a float is again proposed. a piston 82 having a front face exposed to a liquid molding material. The floating piston may be axially slidable in the control cylinder 83, and its stroke is limited by the shoulder 84 in the control cylinder 83. At the rear end of the floating piston 82 is a push rod projection 85 with a push rod head 86; said push rod head 86 being disposed in a recess in the rear housing portion 72 and in an inoperative position lying against the dividing plane 74 of the front housing portion 73. The actuator 88 is constructed similar to the actuator 38 discussed with reference to FIG. 1, and has a control cylinder 89 with a control piston 91 actuated by a spring 90. It is understood that, when inactive, the spring 90 pushes the control piston 91 to its right end position as shown in FIG. 7. The control piston 91 may be actuated by a hydraulic aroa pneumatic pressure medium which pushes the control cylinder 89 through the conduit 92 and through the inlet nozzle 93. The forward pivoting element 94 on the control piston 91 closes the orifice of the nozzle 93 when the unit is in an inactive position, and forming, together with said nozzle 93, a control valve for pneumatic or hydraulic control of the piston 91.

In contrast to the construction shown and discussed in FIG. 1 to 6, in this embodiment, the impact force exerted on the floating piston 82 to the piston 80 of the discharge valve 76 and to the control piston 82 of the actuator 88 is not effected by linear means of an energy transfer element (guide plate 24). in the notch 87 of the part 72 and centrally connected to the pivot axis 97 by the pivoting head member 96. The pivot lever 95 is prefabricated to the rear extension member 98 of the piston 80 of the drain valve 76 and the piston 91 of the actuator 88. at one end, two arms 99 at the free end (Fig. 8), each in horizontal contact with the respective lateral grooves 100 and 101 on said extension member 98 and on the control piston 91. It is understood that this connection with respect to the pivot lever 9 5 movement is realized with the required precision between the branches 99 and the grooves 100 and 101.

In a general sense, the valve assembly of FIG. The operation pattern of 7-8 is similar to that of the valve of Figs. 1 to 6. Thus, if the floating piston 82 is actuated by the incoming liquid molding material penetrating the discharge channel 77, the floating piston, which can perform a very limited stroke, returns the pivot lever 95 so that the discharge valve 76 is closed and held closed by the actuator 88. .

FIG. 9 shows another embodiment corresponding to FIG. 7 and 8. Instead of a floating piston 82 according to FIG. 8 is provided with a diaphragm member 102 acting as a pushing member; said diaphragm element 102 enclosing an outlet channel opening 103 on the face 75 of a front surface 75 of the valve assembly 71 and connected by a ring nut 104 to a housing portion 73. The push rod member 85, which also has a push rod head 86 in contact with the pivot lever 95, extends in this example to the diaphragm member 102. The body portion 73 immediately behind the diaphragm member 102 provides a slightly tapered stop surface 105 that defines the diaphragm member 102. stroke at a magnitude that is only part of the stroke that valve piston 80 passes (Fig. 7)

It will be appreciated that said construction with a diaphragm member could also be used in the embodiment of FIG. 1-6 instead of floating piston 20.

Claims (18)

DEFINITION OF INVENTION A valve assembly for venting injection molds, comprising: a vent means, a vent valve communicating with a vent means, and having an axially slidable valve closure member, and actuating means for controlling said vent valve means from an open position to a closed position; the actuating means comprises energy absorbing means acting on the liquid casting material, which, during casting, passes through the discharge channel from the die casting chamber under pressure and is axially displaced by the kinetic energy transmitted to the energy absorbing means by the liquid casting material to contact these energy absorbing means; and said energy absorbing means being mechanically coupled to an axially movable valve closure member, wherein the energy absorbing means comprises a movable pusher having a stroke whose length is limited only by a portion of the stroke length, the axially movable valve closing member being moved from an open position to a closed position; an axially movable valve closure member adapted to move freely along the trajectory of the energy absorbing means, and said actuating means further transmitting the dynamic force applied to the liquid absorber energy absorbing means by the axially movable valve means closure member. 2. Valve assembly according to claim 1, characterized in that the actuators further comprise a actuator which is operably coupled to the valve actuator moving in the axial direction of the discharge valve means and adapted to maintain the valve actuator in the closed position achieved by the impact of the liquid molding. force on energy absorbing means. 3. Valve assembly according to claim 1, characterized in that the energy absorbing means comprises a floating piston element which is movable 35 in the direction of the control cylinder communicating with the outlet means. 4. Valve assembly according to claim 1, characterized in that the energy absorbing means comprises a diaphragm element which covers the outlet of the outlet. 5. Valve assembly according to claim 1, characterized in that the energy transmission means are loosely coupled to the axially movable pusher and assembled to the axially movable valve closure member of the discharge valve means. 6. Valve assembly according to claim 1, characterized in that the discharge valve means comprises a valve piston element having a plunger element and energy absorbing means arranged in a parallel axis relative to the plunger element. 7. Valve assembly according to claims 5 and 6, characterized in that the energy transfer means comprises a guide plate element which is movable axially and coaxial with respect to the energy absorbing means, the outer edge portion of the guide plate element being prefabricated connecting the discharge valve means plunger element and a plate member lying in front of the energy absorbing means, the spring means being in operation, with the valve assembly in the inactive position. 8. Valve assembly according to claims 5 and 6, characterized in that the energy transmission means comprises a pivoting arm element, which is coupled to the discharge valve means plunger element, said pivoting arm member lying against the energy absorbing means when said valve assembly is in an unemployment situation. 9. Valve assembly according to claim 2, characterized in that the actuator comprises a control cylinder with a pneumatic or hydraulically actuated piston, and the control piston being assembled to the shut-off member movable in the axial direction of the discharge valve means by means of a rigid intermediate coupling. 10. Valve assembly according to claims 7 and 9 or 8 and 9, characterized in that the actuator control cylinder is arranged on a parallel axis with respect to the energy absorbing means and the energy transfer means are coupled to the closing valve movable in the axial direction of the discharge valve means. actuator control piston. 11. Valve assembly according to claim 10, characterized in that the shut-off member movable in the axial direction of the drain valve means and the actuator piston of the actuator are controllably connected to diametrically opposite sides of the guide plate member. 12. Valve assembly according to claim 9, characterized in that the actuator control piston is hydraulically or pneumatically pressed through the control valve element, which is actuated by an axially movable shut-off valve means. 13. The valve assembly of claim 12, wherein said control valve member is a disc valve and the actuator control piston acts as a bottom of the valve valve. 14. Valve assembly according to claim 12, wherein the axially movable closing member control cylinder is provided with an inlet nozzle member having a nozzle channel projecting forwardly into the inside of the control cylinder and the nozzle channel being clamped on the front face of the actuator control piston. , there are spring means inside the control cylinder to press the control piston against the nozzle channel. 15. Valve assembly according to claim 14, characterized in that the pressure of the hydraulic or pneumatic medium for actuating the actuator, the relationship between the cross section of the nozzle channel and the front surface of the control cylinder clamping the nozzle channel and the spring means pressing the control piston to the nozzle channel. , the technical characteristics are selected such that, when the control valve member is closed, the pressure of the hydraulic or pneumatic medium on the inlet nozzle member acting on a portion of the control piston front surface is insufficient to open the control valve member, but when the control valve member is mechanically open, now operating over the entire front surface area of the control piston, is sufficient to allow the control piston to close the drain valve means and keep them closed. 16. Valve assembly according to claim 1, wherein the stroke movement is approximately one-tenth the length of the stroke of the valve closing member moving from the open position to the closed position. 17. Valve assembly according to claim 16, characterized in that the stroke movement is less than 1 mm. 18. Valve assembly according to claim 17, characterized in that the stroke movement is within 0.1 mm.