CH662072A5 - MACHINE FOR MAKING MOLDS. - Google Patents

Description

The invention relates to a machine for producing casting molds.

Various processes and techniques have been introduced in foundry technology in recent years in order to modernize the well-known method of bringing the metal into a desired shape by melting and pouring metal into a casting mold. In the past, a model was used for this purpose in the lower half or the lower case of a molded box. Sand and clay were compacted or pounded around the appropriate locations on the model until the sand and clay assumed the shape of the model, after which the model was removed. The same procedure was used to mold the model in the upper half or in the upper box of the molding box. Suitable core pins were then used if necessary and a sprue system consisting of sprue channels and risers was provided. Then the upper box was placed on the lower box and locked with it and the metal poured.

A known machine for producing casting molds uses a model carrier for receiving a plate on which a part of a model is fastened. The model protrudes upwards into a molding box filled with loose casting sand. The machine allows the mold box to be covered with a platen that supports a plurality of downwardly projecting compaction heads that are moved into the mold box to pound the sand along the model. The compaction heads are then withdrawn and the model carrier with the molding box is moved to the next station.

Another known machine for making molds, which is a machine with only one station, has an upper and lower box model. These models are alternately brought into the working position, compacted and moved out on model carriers. Another known machine of this type has top and bottom box models, both of which are mounted on the same support. Simultaneously or alternately, an upper box and / or lower box is brought into connection with the model in question, after which the mold box is filled with sand, the sand is pounded and the mold box is removed.

In addition to the above-described machines for producing casting molds, there are numerous other designs that are generally suitable and have proven themselves. However, certain models have shapes and / or configurations in which compacting or pounding does not provide fully satisfactory results by making mold boxes that are not fully pounded. This leads to faulty molds which, when used, result in castings that are anything but usable.

Various methods have been proposed to overcome this problem. So e.g. blowing air into

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the loose sand to stir and distribute the sand before pounding. Nevertheless, so-called bridging occurs in some areas of the model, which does not result in mold boxes being properly pounded. These mold boxes must be removed or lead to low-quality castings.

In view of these difficulties, which have hitherto existed, the main aim of the invention is to create a new and improved machine for the production of casting molds by the sand being compacted in an improved manner during the manufacture or production of the casting molds and being influenced with regard to its flowability. In particular, undesirable bridging should be avoided in such a machine or reduced to a permissible level, so that the accumulation of unusable casting molds and / or inferior castings produced on account of such molds is avoided.

This object is achieved by the machine described in claim 1. The oscillating movement caused by the vibrating device before and / or during pounding has the consequence that the molding sand in the molding box is distributed more uniformly along the model and cavities or empty spaces are thereby eliminated. This results in an increased and uniform density of the casting mold.

In a preferred embodiment of the invention, the ramming device and the vibrating device are arranged above or below the mold production station.

The vibrating device preferably comprises an anvil which is arranged substantially below the molding box receiving station and is held in such a way that it can come into engagement with the model carrier located in the station. The vibration device has a shock vibration arrangement, consisting of a motor, an imbalance, a spring device and a frame, which is assigned to the anvil in terms of its effectiveness.

Means can be provided to link the unbalance at the base to the anvil via a spring system.

A particularly preferred embodiment is characterized in that the anvil has a housing that contains a motor that drives the unbalance via a spring system, which results in a linear movement. This spring system is arranged in relation to the anvil in such a way that the model carrier is set into a vertical swinging movement, which leads to a migration of the sand, so that it is compacted along with the compaction heads along the model.

A rotating air vibrator or an electric vibrator can be provided to generate a high frequency, but these vibrators do not give the required force. However, if such high-frequency vibrators are used together with a two-mass system, it is possible to increase the low force in order to apply the force required to set sand in the mold box in motion. A high frequency in the range between about 720 cycles per minute to 3600 cycles per minute in connection with a dual mass system gives the force required to set the sand particles in motion along the model.

Embodiments of the invention are explained in more detail below with reference to the drawing. Show it:

1 is a side view of a machine constructed according to the invention for producing casting molds with parts broken away and shown in section,

2 is an end view of the machine shown in FIG. 1 with parts shown in section,

3 is an enlarged sectional view of a vibration device used in the machine,

4 is an end view of the vibration device shown in FIG. 3 on a further enlarged scale,

5 is an end view of a modification of the vibration device,

Fig. 6 is a side view of the vibrating device shown in Fig. 5, and

7 is a partial sectional view taken along section line 7-7 in FIG. 6. FIG.

A typical example of a machine for producing casting molds according to the invention is shown in FIGS. 1 and 2 and comprises a frame 10. The frame 10 has four vertical columns 12, which are arranged at the corners of a rectangle and at their upper ends by a rectangular one Configuration of two beams 14 and two beams 16 connected together; only one of these carriers is shown. The upper ends of the columns 12 receive fasteners 18 with which the supports 14 and 16 are firmly clamped.

The lower ends of the columns 12 carry feet 20, which in turn rest on a base surface 22, which can be the floor or the like, and are fastened to this surface. A first pair of spaced cross plates 24 extend between end plates, not shown, which are attached to the feet 20 below the beams 16 at the lower end of the frame 10 as well as a second pair of cross plates 26. In addition to the usual function of reinforcing the frame 10, the plates 26 together with four plates 28 (Fig. 1) which extend between and are attached to the plates 26 serve as a guide for the purpose described below.

As shown in Figs. 1 and 2, a pair of horizontally spaced box brackets 30 extend through the frame 10 approximately at the upper ends of the cross plates 24. Each box bracket 30 rotatably holds a plurality of flange rollers 32 which serve as a conveyor around one to move objects to be treated by the machine in and out of the machine. In particular, the part of the conveying device formed by the carriers 30 and the rollers 32 located in the frame 10 forms a molding box receiving station, indicated generally by 34. In one embodiment of the machine, a multi-sided frame 36 is dimensioned such that it can rest on the rollers 32 and is held by the flanges of the rollers in order to removably support a model plate 38, on the top of which at least one model 39 is arranged. A conventional molding box 40 is in turn placed on the model plate 38 in any suitable manner and either contains loose molding sand before the molding box arrives at the box receiving station or such loose molding sand is fed into the molding box in the receiving station.

Above the molding box receiving station 34, the frame 10 holds a so-called compression head, which bears the general reference number 42 and can be of a conventional type. E.g. it can be a construction as it is sold under the name Herman Moldmaster. The compression head 42 has a plurality of fluid cylinders (not shown), each of which contains an extendable piston rod 44 which carries a compression head 46 at its end. As shown in Figs. 1 and 2, the compression heads 46 are arranged close to each other in the form of a plurality of rows and are movable between the position indicated by solid lines at which they enter the molding box 40 and the position indicated by broken lines at which they are at a distance from the molding box 40. As is known, the compression heads 46 are driven downward into the molding box 40 located in the station 34 under the action of a pressure fluid in order to mold the molding sand along the model 39 held by the model plate 38

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to condense. As already mentioned at the beginning, the operation of the compression heads 46 is sufficient in many models in order to obtain satisfactory casting molds. However, it was also pointed out at the beginning that, in the case of a large number of models, in particular those with complex shapes, the action of the compression heads 46 is insufficient to provide satisfactory casting molds, since the molding sand does not easily fill voids and gaps in the model and the sand during the compression by the heads 46 tends to form bridges.

In order to solve this problem, it is proposed according to the invention to provide the machine with a vibration device which is fastened to the frame 10 near the molding box receiving station 34 and which vibrates the molding box 40 located in the station 34 with the molding sand, so that the molding sand enters the Gaps and cavities can flow in and bridges formed can be eliminated before or during the operation of the compression heads 46. As shown in FIG. 1, two such vibration devices 50 are arranged at the lower end of the frame 10 between associated plates 28. As FIG. 2 shows, such vibration devices 50 are also held between the plates 26. FIG. 3 shows an embodiment of a suitable vibrating device 50. Thereafter, it comprises an upper anvil or hammer 52 and a vibration-generating element 55. According to FIG. 4, the upper side 54 of each anvil 52 is slightly spherical. After insertion into the remaining parts of the machine shown in FIG. 1, the upper side 54 of each anvil 52 lies approximately in the plane of the lower edge of the support frame 36. The spherical configuration of the surface 54 ensures that when the support frame 36 is on the rollers 32 rolls into the molding box receiving station 34, the edges of the frame 36 do not hit the edges of the anvil 52 and thereby prevent such movement. Rather, the edges of the frame 36 gradually engage the spherical surface 54 of the anvil 52 as the frame 36 advances into the station 34. The spherical surface 54 therefore prevents the frame 36 from getting stuck during said movement.

A vibration-generating element 55, which has side plates 56 according to FIG. 4, extends downward from each anvil 52. At the lower end of the side plates 56 there is an end plate 58 connecting them to one another, and the anvil 52, the side plates 56 and the end plate 58 form a housing with an interior space, which has the general reference number 60. Arranged in the housing interior 60 is a vertically lying base plate 62, to which a motor 64, which is preferably an electric motor, is fastened. Motor 64 has an output in the form of a shaft 66. Although not shown, shaft 66 extends from both sides of motor 64 and an unbalance 68 is attached to each side. Therefore, when the engine rotates, vibrations are generated.

The upper end of the base plate 62 also holds a horizontal plate 70 inside 60, while a similar plate 72 is suitably attached to the lower end of the base plate 62. Side plates 74 extend between and are attached to plates 70 and 72 as well as plate 62. The oscillatory movement caused when the motor 64 is running is transmitted to the plates 70 and 72, since these are connected to the base plate 62 to which the motor 64 is attached. This movement is in turn transmitted to the anvil 52 due to the provision of a first spring device in the form of spring pairs 76 and 78. In particular, the springs 76 are arranged between the plate 70 and the underside of the anvil 52, while the springs 78 are located between the plate 72 and the top of the end plate 58. As best seen in FIGS. 3 and 6, the springs of each pairing may be separated from each other by a plate 80 attached to the anvil 52 and end plate 58, respectively.

1 and 2, transverse plates 82 extend between the lower edges of the plates 26 and are attached to these lower edges. You in turn hold a second spring device in the form of a coil spring 84 on which the underside of the end plate 58 rests. The springs 84 represent insulation springs for the oscillating devices 50.

As already mentioned, the plates 26 and 28 act as a guide device. In particular, these plates act as a guide device for the anvil 52 and the associated housing formed by the plates 56 and 58. They guide both the anvil and the motor 64 and the associated unbalance rotors 68 in the vertical direction, so that the oscillatory movement transmitted to the anvil 54 is mainly limited to a purely vertical movement.

The device is completed by other load-bearing connecting plates and box girders at the points shown for the purpose of increasing the strength. It is understood that circular positioning discs, e.g. the disk 90 in Fig. 4, can be attached to the various plates concerned at locations where the springs 76, 78, 84 abut the plates so that the springs remain in the desired position. It is understood that the vibrator 50 could operate without the springs 76, 78 by using only the isolation springs 84 and the reaction force from the vibrator to the frame, model plate, model, sand and mold box.

The molding sand used in casting mold manufacturing machines is generally moist, so that the molding sand particles have shear angle forces with one another which, together with external static forces, cause resistance to a relative movement between the particles. It has been found that operating the motor and the unbalance at high frequencies produces a small force that is insufficient to overcome the shear forces or cause sand particles to migrate. However, the use of high frequencies in a two-mass system increases the small forces in such a way that the shear forces between the particles are reduced so that the particles can move relative to one another and can thus be brought into the column of the model. Using a vibrator 50 of the type described above or as shown in U.S. Patent 3,353,815, it has been found that at high frequencies between about 720 to about 3600 cycles per minute in connection with a dual mass system that has a mass Anvil 52, as well as a second mass, the unbalanced rotor 68, creates an unexpected movement of the sand particles relative to one another, so that the sand particles can move into small openings, cavities and other irregularities of the model 39 to fill them.

During operation, the carrier frame 36, the model plate 38 and the molding box 40 with the molding sand located therein are moved along the rollers 32 into the molding box receiving station 34. During this process, the compression heads 46 are in the position indicated by broken lines in FIGS. 1 and 2. As soon as the molding box 40 has taken the correct position in the station 34, the vibration device 50 is put into operation in order to work in the high-frequency range between 720 and 3600 cycles per minute. The oscillating movement is transmitted to the anvils 52, which oscillate in the vertical direction due to the guidance provided by the plates 26 and 28. As a result, the top 54 of each anvil 52 comes into contact with the frame 36, so that this also in

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Vibrations are offset and thus the swinging movement is transmitted to the molding box 40 via the frame. The sand in the molding box therefore also vibrates, which leads to a movement of the sand particles into the cavities and gaps in the model 39. The oscillating movement acting on the sand causes any sand bridges to collapse, so that empty spaces in the molding box 40 are avoided. At any suitable time, either approximately at the same time that the vibrating device 50 is switched on or shortly thereafter, the compacting head 42 is activated so that the compacting heads 46 are moved into the molding box 40 and exert compacting forces on the sand so that the sand is in a close relationship the shape of the model 39 is brought. The vibration device 50 is switched off as soon as the compacting heads 46 have pressed the sand substantially along the model. A further effect of the compression heads 46 after any vacancies have been removed leads to a compression of the sand, so that the mold boxes are always fully tamped. This in turn leads to mold boxes which are satisfactory in every respect and high-quality castings produced with such mold boxes.

1 and 2 show that the solid line position of the plurality of compacting heads 46 is on a substantially common plane, in practice the sand becomes different at different locations in the molding box partly due to the presence of the model and partly from less dense sand that has accumulated in one place in contrast to another. As a result, the individual compaction heads 46 generally end at different height levels - they lie higher and lower in the area of the corners above the model. After the molding box 40 and the carrier 36 have come out of the receiving station 34, a further mixture of sand and binder is added to fill up the molding box. Suitable risers and sprues are either molded into the sand (e.g. as part of the model) or cut into the sand of the molding box after compaction. The movement of the sand caused by the high frequency vibrator 50 which results in the cavities and gaps in the model being filled and bridging in the sand removed before or at the same time as compaction creates an improved mold after the compaction of the sand in the molding box.

Instead of the vibration-generating system, consisting of the motor and the unbalanced rotor, a rotating air vibrator or an electric vibrator can also be used if the condition is met that these vibrators in the high-frequency range between about 720 cycles per minute and 3600 cycles per Minute can be operated.

A modified embodiment of the invention is shown in Figs. 5-7. A vibrating device 150 then has an anvil 152, which has two anvil surfaces 153, 153 (FIG. 6) spaced apart from one another and a common connection base part 157. Suitable guides 159 are provided in order to guide the anvil 152 in the vertical direction both with vibration and up and down movement, which will be discussed below. The anvil 152 is held by a rigid plate 161 which extends below the two anvil surfaces 153, 153. A plurality of sets of springs 163 are arranged between the rigid plate 161 and an excitation plate 165 which is supported on insulation springs 167 which are attached to platforms 169 on the floor. Three sets of springs 163 are provided, one set being aligned with one pair of insulation springs 167, a second set with the other pair of insulation springs 167, and the third set being located at the center of the anvil 152, plate 161 and exciter plate 165 . A rigid mounting platform 171 is attached to the floor and supports a pair of inflatable air brackets 173 connected to the underside of the excitation plate 165. The air brackets 173 are arranged with respect to the center of the anvil such that both spaced surfaces 153, 153 of the anvil 152 are raised or lowered simultaneously when air is introduced into the air brackets 173 or the air is released from the brackets. A source of compressed air is used to expand the air brackets 173, which are conventional types on the market.

A pair of vibration generating elements 155 is provided and includes a motor 164 and a pair of motor-driven unbalanced rotors 168. Each motor 164 is supported by a bracket 177 attached to the underside of the excitation plate 165. The brackets 177 are attached symmetrically on opposite sides of the air brackets 173 to the exciter plate 165, so that there are two vibration-generating elements 155 relative to the two surfaces of the anvil 152, so that a uniform oscillating movement is generated on both surfaces. The vibration generating elements 155 are actuated in opposite directions by the motors 164, so that both surfaces of the anvil 152 are given a pure vertical swinging motion.

The vibration generating system is a two-mass system in which one mass represents the anvil 152 and the other mass the unbalanced rotors 168. The dual mass system in conjunction with the motors 164 and the unbalanced rotors 168, which operate at high frequencies in the range of about 720 cycles per minute to 3600 cycles per minute, cause the unexpected phenomenon in the wet sand of the mold box that the sand particles are relative to each other move and propagate to fill the gaps and voids in the model.

In operation, a frame 36, a model carrier 38 with a model 39 and a molding box 40 with wet sand are moved into the box receiving station. The anvil 152 and the vibration generating elements 155 are in the lowered position due to the collapsed air brackets 173. The vibration generating elements 155 can be started while the anvil is in the lowered position, or the vibration generating elements can be operated after the air brackets 173 have been inflated to lift the anvil 152 into contact with the frame 36. In any case, the anvil, upon contact with the frame 36, creates a high frequency vibratory motion on the mold box which sets the sand particles in motion and work relative to each other so that the cavities and gaps in the model 39 fill. At an appropriate time, the compacting head 42 is lowered and the heads 46 are pressed against the sand to compact it into a configuration corresponding to the model. The air can be released from the brackets 173 when the vibrating elements are in operation and during the compression of the sand by the compression heads 46, so that the anvil is released from the frame and molding box. This prevents damage to the freshly compacted casting mold by the vibration elements, which continue to set the mold box in vibration after the compacting heads 46 have been moved out of the mold box.

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Claims (14)

662 072 PATENT CLAIMS 1. machine for the production of casting molds, characterized by a frame (10) with a molding box receiving station (34), a ramming device (42), which is held on the frame (10) for movement in the direction of and away from the molding box receiving station (34), so that it into a molding box (40) located on the receiving station (34) for pounding the content therein is movable; and vibrating means (50) held on the frame (10) near the molding box receiving station (34) for vibrating a molding box (40) and its contents when the molding box (40) is in the receiving station (34) , and during the operation of the ramming device (42). 2. Machine according to claim 1, characterized in that the ramming device (42) and the vibrating device (50) are arranged on opposite sides of the molding box receiving station (34). 3. Machine according to claim 1, characterized in that the vibration device (50) at least one Am-boss (52, 152) which is arranged on one side of the molding box receiving station (34) for engagement with a molding box support frame (36) located in the station, and has a vibration-generating element (55, 155) which is assigned to the anvil according to its effect. 4. Machine according to claim 3, characterized by a resilient attachment of the vibration-generating element (55, 155) on the frame (10) and a spring device (76, 78; 163) which the vibration-generating element (55,155) and the anvil (52,152) with each other connects. 5. Machine according to claim 3, characterized in that a device (173) for lifting and lowering the vibration device (155) in and out of contact with the mold box support frame (36) is provided. 6. Machine according to claim 5, characterized in that the means for lifting and lowering consists of a pair of inflatable air brackets (173). 7. Machine according to claim 1, characterized in that the ramming device (42) comprises a plurality of compression elements (46) and that the vibration device (50) is arranged below the molding box receiving station (34). 8. Machine according to claim 7, characterized in that the molding box receiving station (34) has a conveyor to support the molding box in the receiving station and to move in and out of the station. 9. Machine according to claim 7, characterized in that the vibration device (50) comprises two masses (52, 64) interconnected via a spring device (76, 78) and a vibration-generating element (68). 10. Machine according to one of claims 1-9, characterized in that the receiving station (34) is designed as part of a substantially horizontal conveyor device (30, 32) which extends through the frame (10), that the vibration device (50 ) in the lower end of the frame (10) provided motor (64; 164) with rotary drive and at least one unbalanced rotor (68,168) which is connected to and driven by the motor, and that the motor with respect to one movement is guided in a substantially vertical direction. 11. Machine according to claims 4, 9 and 10, characterized in that the two interconnected masses are formed by the motor (64, 164) and the anvil (52, 152). 12. Machine according to claim 11, characterized in that the anvil (52) has a spherical top (54). 13. Machine according to claim 11, characterized in that the anvil has a housing which contains the motor (64), the unbalanced rotor (68) and the spring device (76,78), wherein the spring device comprises at least two springs, which between close the motor and rest against the housing. 14. Machine according to one of the preceding claims, characterized in that the vibrating device can be operated in the high-frequency range from approximately 720 cycles per minute to approximately 3600 cycles per minute.