DE102019108574A1 - Guide device in a molding machine and molding machine with such a guide device - Google Patents

Abstract

A guide device in a molding machine (FM) and a molding machine (FM) with such a guide device (FE) are specified, which comprises an upper mold part (FO) for transferring a compressive force to at least one printing plate (DP) which extends in the direction of insertion (ER) can be introduced into an opening (OE) of a lower mold part (FU), the upper mold part (FO) being assigned a magnetizable first guide element (FE1) and a magnetizable second guide element (FE2) assigned to the lower mold part (FU), which are located outside the opening (OE ) overlap without contact in a guide area at at least two positions along the insertion direction (ER) so that the lower mold part (FU) runs transversely to the insertion direction (ER) by means of a magnetic force between the first guide element (FE1) and the second guide element (FE2) the predefined distance (SP) to the upper part of the mold (FO) when inserting the pressure plate (DP) into the lower part of the mold (FU).

Description

The invention relates to a guide device for a molding machine and molding machine with such a guide device.

The production of concrete moldings, such as. B. paving stones typically takes place in the context of a machine production by means of a molding machine with a stamp unit and a molded lower part designed as a mold, in which the stamp unit can engage. One or more mold cavities that are open upwards and downwards are usually formed in the lower mold part. The lower part of the mold is placed on a horizontal base with a lower boundary plane of a stone field, which closes the lower openings of the mold. The mold cavities are filled with a quantity of concrete through the upper openings, which is then pressed over pressure plates arranged on the stamp unit, in which the pressure plates are sunk into the mold cavities through the upper openings. Subsequently, by shaking the base, the concrete mass solidifies to form stable concrete molded parts. These are removed from the mold through the lower openings in the mold cavities.

The stamp unit is connected to a typically hydraulically actuated vertical movement unit of the molding machine and can be moved vertically by means of this. The connection can be made in a customary construction via a load unit, which usually forms an upper part of the mold with the stamp unit as a unit that can be handled in a uniform manner. By means of a stop on the stamps of the stamp unit, a uniform stone height is achieved even if the amount of concrete is differently compacted.

In known molding machines, the connection between the upper mold part and the lower mold part is of particular importance. For example, from the DE 36 38 207 A1 It is known that with molds of this type, if the upper part of the mold is inadequately aligned with the lower part of the mold, there is a risk of the plunger colliding with an upper side of the lower mold part. This occurs in particular when the upper mold part is guided into the lower mold part in the molding machine in order to shape and compact the molded concrete part to be produced. According to solutions known from the prior art, attempts have been made to circumvent this by aligning the upper part of the mold exactly with the lower part of the mold and providing corresponding inlet bevels on the mold cavities, which facilitate the introduction of the pressure plates.

From the DE 10 2005 048 930 A1 a block mold for the production of concrete blocks is known which comprises an upper mold part with at least one punch with a pressure piece and a lower mold part with at least one mold cavity for use in a block molding machine, the lower mold part being movable up and down in a block molding machine. The lower part of the mold can be placed on a base of the block of the block molding machine and the upper part of the mold can be coupled to a machine holder of the block-making machine that can be moved up and down. A filling box of the block molding machine can be moved over the lower part of the mold and the upper part of the mold and / or the lower part of the mold has clearance to a machine frame of the block molding machine. A centering device is provided for aligning the lower mold part and the upper mold part in an xy plane. Exact centering of the two molded parts with respect to one another is brought about here, with a conical section on the centering device slowly releasing the centering of the molded parts again after the pressure piece has dipped into the mold cavity.

From the DE 10 2015 103 829 A1 a device for the production of concrete moldings in a molding machine is known which comprises an upper mold part with at least one plunger for transmitting a force to at least one pressure plate, the pressure plate being insertable in the vertical direction into an opening of a mold cavity in a lower mold part, the lower mold part from a frame is surrounded which has a guide means connected to the upper mold part, which guide means is designed such that the lower mold part can be tilted against the upper mold part from the vertical direction during the engagement of the pressure plates in the openings of the mold cavity.

The object of the invention is to create a guide device in a molding machine and molding machine with such a guide device, in which the centering between the upper and lower mold parts is further improved by the guide device exhibiting little wear.

This object is achieved by the features of claim 1. Further advantageous embodiments of the invention are each subject matter of the subclaims. These can be combined with one another in a technologically sensible way. The description, in particular in connection with the drawing, additionally characterizes and specifies the invention.

According to the invention, a guide device is created in a molding machine which comprises an upper mold part for transmitting a compressive force to at least one pressure plate which can be inserted in the insertion direction into an opening of a lower mold part, the upper mold part having a magnetizable first guide element and a magnetizable second guide element are assigned to the lower mold part, which overlap without contact in a guide area outside the opening at at least two positions along the insertion direction, so that the lower mold part by means of a magnetic force between the guide elements has a predefined distance to the insertion direction The upper part of the mold adheres to the lower part of the mold when the pressure plate is inserted.

Accordingly, a guide device is created in which the upper mold part and the lower mold part of the molding machine are aligned with one another by means of a magnetic guide. Because of the contactless guidance by means of the guide device according to the invention, it is thus possible to avoid or reduce wear on the guide device. In addition to the improved service life compared to mechanical guides, there is another advantage that vibration energy losses are reduced. Usually, in the production of concrete blocks, the lower part of the mold is further compressed by means of a load unit via a vibrating table after the amount of concrete has been filled in and a pressure has been applied. However, mechanical guidance between the upper part of the mold and the lower part of the mold removes energy from this process, which must be taken into account when designing the operating parameters of the vibrating table. The magnetic guide according to the invention provides a remedy here. Due to the magnetic guidance by means of the two guide elements, it can be ensured that the pressure plates of the upper part of the mold cannot come into contact with the side walls in the lower part of the mold, whereby possible damage to both the lower part of the mold and the pressure plates can be prevented. The run-in chamfer on the walls of the lower mold part, which has hitherto been customary in the prior art, can thus be omitted, whereby corresponding wear in the area of the upper edge of the lower mold part can also be avoided. A subsequent, very time-consuming welding of the upper edge of the lower part of the mold is therefore no longer necessary. However, this also reduces the production costs of the lower part of the mold, since the elevation of the shape of the lower part of the mold can be chosen to be lower, since no area needs to be provided for the run-in chamfer.

According to one embodiment of the invention, in order to generate the magnetic force, the first guide element or the second guide element has a plurality of permanent magnets or electromagnets on a top side facing the other guide element in the guide area.

While the provision of the magnetic force by means of permanent magnets is a simple and inexpensive way of creating a magnetic guide device, in other applications it can be advantageous to make the magnetic bearing force appropriately adjustable by means of electromagnets. Both the specification of a predetermined value and the active adjustability for damping the relative movement between the upper part of the mold and the lower part of the mold are possible. The magnets in the guide area can be designed in different ways, with provision being made to arrange appropriate permanent magnets or electromagnets both on the first guide element and on the second guide element. However, a magnetic bearing is also conceivable by arranging magnets only on the first guide element or on the second guide element, since, for example, corresponding eddy currents would be generated on the other guide element. In addition to a large number of individual magnets, which can be arranged in a matrix form, for example, it is also possible to attach large-area magnets. The guide area is provided with magnets in such a way that the magnetic force is maintained along the direction of insertion of the printing plates over a greater distance, so that the lower part of the mold can be centered on the upper part of the molding machine. Switching off the electromagnets can also increase the efficiency of the shaking process, as no more energy is extracted from it. With the arrangement of the large number of individual magnets in matrix form, the field course and thus the magnetic force between the first guide element and the second guide element can be influenced by selecting a corresponding polarity of individual magnets. It is also conceivable here that a residual force is also applied in the axial direction, i.e. can be generated parallel to the direction of insertion.

According to a further embodiment of the invention, the first guide element and the second guide element are arranged on two diagonally opposite corner areas or in square areas of the opening.

The guide device according to the invention creates a translational degree of freedom along the insertion direction, with a corresponding centering taking place in the plane of the pressure plates. The centering can take place via two guide areas, preferably attached to opposite corners of the lower mold part, or in all square areas. In principle, two possibilities are conceivable here. On the one hand, the corner areas can each surround an opening. In this case, the lower mold part has guide devices for each combination of pressure plate and associated opening. Usually, a plurality of openings, each provided with its own pressure plate, complement one another to form a mold cavity in the lower mold part, with corresponding guide elements being able to be arranged at two or four positions in the corner areas of the lower mold part. While the first variant creates a magnetic guide for each printing plate, the second variant provides a magnetic guide for an entire molding machine.

The guide device can be designed in such a way that the lower mold part can be tilted against the upper mold part along the insertion direction. The guide device would thus create a degree of freedom of rotation in which the tilt angle is typically limited to 1 to 2 °, as has already been advantageously implemented from the prior art for mechanical guides.

The guide area, in which the magnets of the first guide element and of the second guide element typically face one another, can be designed in different ways. It is thus possible for the first guide element and the second guide element to be designed with corresponding surfaces, which are designed, for example, as angled wall surfaces along the insertion direction. Typically, an L-shaped or V-shaped configuration of the guide elements was selected here, the second guide element being able to be arranged on a frame surrounding the opening and the first guide element being able to be arranged transversely to the insertion direction to the second guide element.

In another embodiment, the first guide element or the second guide element can enclose the other guide element, in which case the first guide element can preferably be designed in the form of a pin and the second guide element in the form of a socket.

According to this embodiment, the insertion element completely surrounds the other, so that both a magnetic guide and a magnetic bearing can be formed which allow the upper mold part to be centered with respect to the lower mold part.

Furthermore, a molding machine for the production of concrete blocks is specified with a guide device as described above.

In such a molding machine, the magnetic force can be adjustable or controllable. The magnetic force is maintained during the threading of pressure plates into the opening, during the compaction of the concrete quantity or during a demolding process of the concrete block.

Advantageously, the magnetic force can be reduced or completely absent during a shaking process in order not to withdraw any energy from the shaking process through the guidance of the lower mold part in the upper mold part.

The magnetic force can also be present when the lower mold part is installed in the molding machine, so that the upper mold part can be centered on the lower mold part during installation.

The guide device can advantageously support the installation of the lower part of the mold in the molding machine with an inlet chamfer arranged on the first guide element or the second guide element.

• 1 eine Formmaschine mit einer Führungseinrichtung gemäß einer Ausführungsform der Erfindung in einer perspektivischen Seitenansicht,
• 2a die Formmaschine aus 1 in einer Ansicht von ihrer Unterseite,
• 2b die Formmaschine aus 2a in einer Detailansicht,
• 3 die Führungseinrichtung aus 1 in einer weiteren perspektivischen Seitenansicht,
• 4 eine Formmaschine mit einer Führungseinrichtung gemäß einer weiteren Ausführungsform der Erfindung in einer perspektivischen Seitenansicht,
• 5a die Formmaschine aus 4 in einer Ansicht von ihrer Unterseite,
• 5b die Formmaschine aus 5a in einer Detailansicht,
• 6 die Führungseinrichtung aus 4 in einer weiteren perspektivischen Seitenansicht.

Some exemplary embodiments are explained in more detail below with reference to the drawings. Show it:

• 1 a molding machine with a guide device according to an embodiment of the invention in a perspective side view,
• 2a the molding machine off 1 in a view from below,
• 2 B the molding machine off 2a in a detailed view,
• 3 the guide device 1 in another perspective side view,
• 4th a molding machine with a guide device according to a further embodiment of the invention in a perspective side view,
• 5a the molding machine off 4th in a view from below,
• 5b the molding machine off 5a in a detailed view,
• 6th the guide device 4th in another perspective side view.

In the figures, identical or functionally identical components are provided with the same reference symbols.

In 1 is a molding machine FM shown, which is suitable for the production of concrete moldings.

The molding machine FM is in 1 shown in a perspective side view. Man recognizes that a mold top FO with a variety of printing plates DP is in connection, the upper mold part in the direction of an insertion direction via a loading unit (not shown) HE can be moved. Between the pressure plates DP and the mold top FO are corresponding stamps ST provided that the printing plates DP on the upper part of the mold FO hold.

The printing plates DP reach into corresponding openings OE a lower part of the mold FU one. In the openings OE becomes when operating the molding machine FM a quantity of concrete poured in, so that after penetration of the pressure plates DP along the direction of insertion HE a compression of the amount of concrete is possible. The lower part of the mold FU is usually placed on a vibrating table.

In addition to the production of a single molded concrete block, the lower part of the mold is typically used FU in several openings OE divided over appropriately shaped side walls SW are separated from each other. A plurality of such openings is typically referred to as a mold cavity. On the upper edge KA the side walls SW of the lower part of the mold FU According to the invention, no run-in bevel is provided. This is achieved by centering the upper part of the mold FO and lower part of the mold FU takes place by means of a guide device, which as in 1 is shown, a first guide element FE1 and a second guide element FE2 having. The first guide element FE1 is assigned to the upper part of the mold. The second guide element FE2 is the lower part of the mold FU assigned and can be attached to a portion of the lower mold part FU be arranged, which corresponds to a frame formed outside of the mold cavity.

The positioning of the guide device FE by means of the first guide element FE1 and the second guide element FE2 is described below with reference to the 2A and 2 B explained again in more detail. 2A shows the underside of the lower mold part opposite to the direction of insertion HE . 2 B corresponds to a detailed view of a corner area 2A . In this example the lower part of the mold FU multiple openings OE on that from the side wall SW as a mold cavity FN are separated.

You can see that on the lower part of the mold FU in all four corner areas EB each the first guide element FE1 and the second guide element FE2 are arranged. The second guide element FE2 is formed with wall surfaces on the lower part of the mold, which run along the direction of insertion HE can have an angle of 90 ° to each other. At a predefined distance, in 2 as a gap SP indicated, is the first guide element FE1 that corresponds to the upper part of the mold. Due to the large number of magnets MA on the respective surfaces of the first guide element FE1 and the second guide element FE2 are formed, the guidance of the lower mold part takes place FU relative to the mold top FO by means of a magnetic force that ensures appropriate centering. The magnets MA can be designed both as permanent magnets and as electromagnets. In addition to attaching the guide device in all four corner areas EB it is also possible, for example, only at two diagonally opposite corner areas EB to train.

In 3 is the guiding device FE again individually without the corresponding components of the molding machine FM shown. It can be seen that the first guide element FE1 along the direction of insertion HE a first expansion AD1 having that is greater than a second dimension AD2 of the second guide element FE2 is chosen. The first guide element thus overlap FE1 and the second guide element FE2 along a guide area which extends along a larger section along the insertion direction HE ensures the appropriate centering. The first guide element FE1 is with a chamfer EF and the second guide element FE2 formed with a corresponding further inlet chamfer EF ', which the assembly of the lower mold part FU and mold top FO should facilitate.

In 4th a further embodiment of the invention is shown. In contrast to the embodiment according to FIG 1 to 3 are the guide elements here FE1 and FE2 not formed with corresponding surfaces, but are arranged so that the first guide element FE1 in the second guide element FE2 intervenes. The second guide element FE2 therefore surrounds the first guide element FE1 Completely. In the 5A and 5B is the corresponding arrangement of the guide elements FE1 and FE2 in the corner areas EB the lower part of the mold shown accordingly. One recognizes, especially in 5B that again between the first guide element FE1 and the second guide element FE2 a corresponding gap forms.

In 6th is the guiding device FE again shown without the components of the molding machine. It can be seen that the first guide element is designed in the form of a pin, which in turn has a large number of magnets in the guide area MA is provided on its top. The second guide element FE2 is designed in the form of a socket or a hollow cylinder, on the inside of which also has a large number of magnets MA are arranged. The first guide element FE1 is again with a chamfer EF educated.

The magnets MA can both when executing according to 4th to 6th as well as in the execution according to 1 to 3 be formed by both permanent magnets and electromagnets. While in the first case a simple but nevertheless reliable guidance between the upper part of the mold FO and lower part of the mold FU is possible, control or adjustability of the magnetic force can also be achieved in the second case.

The controller can control the magnetic force at different times when the molding machine is in operation FM influence accordingly, for example during a threading of printing plates DP into the opening OE , during the compaction of the concrete in the opening OE when the pressure plates penetrate DP or to maintain the molded concrete block during a demolding process. Advantageously, the magnetic force can be reduced or completely absent during a vibrating process, so that no energy is lost to the vibrating process through the guidance of the lower mold part FU in the upper part of the mold FO to withdraw.

The features indicated above and in the claims as well as those which can be inferred from the figures can advantageously be implemented both individually and in various combinations. The invention is not limited to the exemplary embodiments described, but can be modified in many ways within the scope of the skilled person.

List of reference symbols

AD1

first expansion

AD2

second expansion

DP

printing plate

EB

Corner area

EF

Run-in chamfer

EF`

further run-in bevel

HE

Direction of insertion

FE

Guide device

FE1

first guide element

FE2

second guide element

FM

Molding machine

FN

Mold cavity

FO

Mold top

FU

Lower part of the mold

KA

upper edge

MA

magnet

OE

opening

SP

gap

ST

stamp

SW

Side wall

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 3638207 A1 [0004]
• DE 102005048930 A1 [0005]
• DE 102015103829 A1 [0006]

Claims (15)

Guide device in a molding machine (FM), which comprises an upper mold part (FO) for transmitting a compressive force to at least one pressure plate (DP) which can be inserted in the insertion direction (ER) into an opening (OE) of a lower mold part (FU), the upper mold part (FO) a magnetizable first guide element (FE1) and a magnetizable second guide element (FE2) are assigned to the lower mold part (FU), which overlap without contact in a guide area outside the opening (OE) at at least two positions along the insertion direction (ER), so that the lower mold part (FU) by means of a magnetic force between the first guide element (FE1) and the second guide element (FE2) has a predefined distance (SP) from the upper mold part (FO) running transversely to the insertion direction (ER) when the pressure plate (DP) is inserted in the lower part of the mold (FU). Guide device according to Claim 1 , in which the first guide element (FE1) or the second guide element (FE2) has a plurality of permanent magnets or electromagnets in the guide area on an upper side facing the other guide element in order to generate the magnetic force. Guide device according to Claim 1 or 2 , in which the first guide element (FE1) and the second guide element (FE2) are arranged in two diagonally opposite corner areas (EB) or in four corner areas (EB) of the opening (OE). Guide device according to Claim 3 , in which the corner areas (EB) each surround an opening (OE). Guide device according to Claim 3 , in which a large number of openings (OE) complement each other to form a mold cavity (FN), which is surrounded in the corner areas (EB) by the first guide element (FE1) and the second guide element (FE2). Guide device according to one of the Claims 1 to 5 , in which the lower mold part (FU) can be tilted against the upper mold part (FO) along the insertion direction (ER). Guide device according to one of the Claims 1 to 6th , in which the first guide element (FE1) and the second guide element (FE2) are designed with corresponding surfaces. Guide device according to Claim 7 , in which the first guide element (FE1) and the second guide element (FE2) are each formed with two wall surfaces which are angled to one another along the insertion direction (EB). Guide device according to Claim 7 or 8th , in which the second guide element (FE2) is arranged on a frame surrounding the opening (OE) and the first guide element (FE1) is arranged transversely to the insertion direction (ER) at a distance from the second guide element (FE2). Guide device according to Claim 7 , in which the first guide element (FE1) or the second guide element (FE2) surrounds the other guide element Guide device according to Claim 10 , in which the first guide element (FE1) in the form of a pin and the second guide element (FE2) in the form of a socket. Forming machine (FM) for the production of concrete blocks with a guide device (FE) according to one of the Claims 1 to 11 . Molding machine after Claim 12 , in which the magnetic force is adjustable or controllable. Molding machine after Claim 12 or 13 , in which the magnetic force is maintained during the threading of pressure plates (DP) into the opening (OE), during compression of the concrete quantity or during a demolding process of the concrete block. Molding machine according to one of the Claim 12 to 14th , in which the magnetic force is maintained when the upper part of the mold (FO) and the lower part of the mold (FU) are centered during installation.

Images