EP1124656B1 - Method and plant for continuously producing construction elements - Google Patents

Description

The invention relates to a method and a system for continuous production of components that consist of two parallel, flat wire mesh mats crossing each other and longitudinal and welded to each other at the crossing points Cross wires, from which wire mesh mats in a predetermined, mutual spacing, straight bridge wires as well one between the wire mesh mats, of which Bridge wires penetrated insulator exist.

From WO 96/03234, which forms the basis for the preamble of claims 1 and 7 forms, a system is known, the two storage magazines for wire mesh webs or wire mesh mats, Straightening and cutting devices for each wire mesh web, one Feeding device for insulating plates, at least one group of Bridge wire supply coils including associated bridge wire feed and Cutting devices, bridge wire welding devices, bridge wire trimming devices, and several coupled together Conveyor elements for the wire mesh webs or wire mesh mats, for the insulating body and for the component.

In this known system, two of each have a supply spool peeled, straight wire mesh in Wire mesh mats of the desired length separated and so generated wire mesh mats in one of the desired thickness of the Component to be produced corresponding mutual distance brought into parallel position. The supply has already been cut to length Wire mesh mats are also provided. In the space between the wire mesh mats and at a selectable distance an insulating body is inserted from the wire mesh mats, which either separated from an insulating material web or is fed as a single plate. The two wire mesh mats together with the insulating body, the bridge wire feed and fed to cutters in which first at the same time several wires in vertical rows one above the other withdrawn from supply spools, straightened and in bridge wires required length, and then the bridge wires from the side through the mesh of the two wire mesh mats and pushing the insulator through each bridge wire with its ends near one wire each of the wire mesh mats comes to rest. The semi-finished so produced Component is fed to the bridge wire welding devices, in which the ends of the land wires match the wires of the wire mesh mats be welded. The component is final fed to the trimming devices, in which the wires of Wire mesh mats projecting lateral projections of the bridge wires be separated.

A disadvantage of the known system is that the production an endless sheet of insulating material is very complex and mainly due to the supply of this endless sheet of insulating material the stiffness of the insulating material has very large radii of curvature and therefore requires a lot of space. The well-known facility also gives no references to the embodiment of the Cutting device for the insulating material web.

The object of the invention is a method and a system to create the type specified in the introduction, which the described Avoids disadvantages of the known system and enables an endless, easily manufactured insulating material web feed the system and in a simple manner the insulating body of the component from the insulating material web separate.

The invention thus relates to a method for continuous production of components, in which two parallel, flat wire mesh mats crossing and crossing each other longitudinal and welded to each other at the crossing points Cross wires advanced in a production line and between the wire mesh mats an insulating body is inserted, which in a selectable length of an endless, coherent, insertable insulating material web is separated, whereupon the straight bridge wires passed through the insulating body and their ends are welded to the wire mesh mats, so that they are at a predetermined mutual distance are held. The method according to the invention is characterized by this from that to form the endless, coherent insulating mat web individual insulation plates individually and one after the other conveyed into the production line and in its longitudinal direction be pushed forward, the end faces being successive Insulating plates at least non-positively connected become.

Preferably, to create the endless, contiguous Isoliermaterialbahn the insulating plates with their End faces are positively and non-positively by clamping together connected. According to a further feature of the invention, the End faces are positively and non-positively thanks to a tongue and groove clamping connection connected with each other.

Alternatively, it is provided that insulating plates with planes End faces are used and to create the endless, contiguous sheet of insulating material on at least one end face successive insulating plates an adhesive or the front surface is provided with a self-adhesive film.

According to a further alternative, insulating plates are used flat end faces are used and it is used to generate the endless, coherent sheet of insulating material the end faces the successive insulating plates are heated together and connected by welding.

The invention further relates to a plant for carrying out of the process, with two storage magazines for wire mesh webs, with straightening and cutting devices for each wire mesh web, with a feed device for insulating plates, with a cutting device for separating an insulating body from the insulating material web, with at least one group of bridge wire supply coils including the associated bridge wire feed and Cutting devices, with bridge wire welding devices, with Bridge wire trimming devices, and with several coupled together Conveyors for the insulator, for the Wire mesh webs or for wire mesh mats, for the mesh body and for the component, characterized in that a Feed device for feeding the insulating plates for formation the insulating material web under non-positive and preferably also positive connection of successive Insulating plates are provided and that the cutting device can be moved parallel to the production line.

Fig. 1 eine schematische Draufsicht eines Ausführungsbeispiels einer Anlage gemäß der Erfindung;

Fig. 2 ein weiteres Ausführungsbeispiel für die Materialzuführung zur Anlage gemäß der Erfindung und

Fig. 3 ein weiteres Ausführüngsbeispiel für die Materialzuführung zur Anlage gemäß der Erfindung.

Further features and advantages of the invention are explained in more detail below using exemplary embodiments with reference to the drawings. Show it:

Figure 1 is a schematic plan view of an embodiment of a system according to the invention.

Fig. 2 shows another embodiment of the material supply to the system according to the invention and

Fig. 3 shows a further exemplary embodiment of the material feed to the system according to the invention.

The system shown in Fig. 1 is used for continuous Manufacture of a component P consisting of two parallel, flat wire mesh mats M, M 'crossing each other and welded together at the crossing points Line and cross wires L and Q, from the two wire mesh mats M, M 'at a predetermined mutual distance, extending obliquely between the wire mesh mats M, M ', straight bridge wires S, S ', each end with a wire L and Q of the two wire mesh mats M, M 'are welded, as well as one between the wire mesh mats M, M 'and with predetermined distance from these arranged, dimensionally stable Insulating body K, for example made of a foamed plastic sheet. The structure and technical characteristics of a such component P are, for example, in the application WO 94/28264 described in detail.

The plant consists of seen in production direction P1 an insulating material feed device 1, a wire mesh feed device 2, a wire mesh mat feeder 3 ', two bridge wire feeders 4, 4', two Bridge wire welding devices 5, 5 ', two edging devices 6, 6 ', a cutting device 7 for severing the insulating material web B and from a component conveying device 8.

The insulating material supply device 1 has an insertion device 9 on which to form the insulating body K of the component P certain insulating plates I1 accordingly the arrow direction P2 of the production line Z-Z of the plant supplies. The insulating plates I1 are on one end face a groove N and on the other opposite end face provided with a spring F, tongue and groove formed in this way are that the spring of an insulating plate I1 positive and non-positive fits in the groove of another insulating plate. The Insert device 9 consists of two working cylinders, the Piston rods are moved according to the double arrow P3 and are provided with a pressure plate 11 at their end. In the Production line Z-Z is a conveyor belt 12 which is arranged with Driven by a conveyor drive 13 in the production direction P1 and the insulating plate I1 along in this direction the Z-Z production line. On a frame 14 a transversely movable stop frame 15 is attached, which the Feed movement P2 of the insulating plates I1 limited and the location of the insulating plates I1 in the Z-Z production line. At the inlet side of the conveyor belt 12 is a feed device 16, for example a working cylinder. The piston rod of the working cylinder 16 is corresponding the double arrow P4 movable and with one to the one Grooved end face of the insulating plate I1 adapted Pressure plate 17 provided. With the help of the feed device 16 the insulating plate I1 'located on the conveyor belt 12 according to arrow P1, additionally pushed around the insulating plate I1 'relative to the insulating material web already formed B to move and thus the insulating plate I1 'positive and non-positive to connect to the end of the insulating material web B. and an endless, coherent insulating material web B. produce. The spring of the insulating plate I1 'engages in the Groove of the terminal element of the insulating material web B. Die The design of the grooves and tongues is one on the other matched, which is a positive and non-positive clamping connection arises, both the alignment of the insulating plates to be connected I1, I1 'as well as their fixed connection with each other.

At the conveyor belt 12 one closes the whole Production line Z-Z extending transport chain 18 which is driven according to the production direction P1 and the Insulation material web B in the production line Z-Z in cycles moved according to the production direction P1. The transition point between the conveyor belt 12 and the beginning of the transport chain 18 is limited laterally by side plates 19, 19 ' when connecting adjacent insulating plates I1 'to form the Insulation material web B a lateral evasion of the insulation panels To avoid I1 '. The distance between the side plates 19, 19 ' is adjustable to even with different thicknesses of the insulating plates I1 'to ensure the closest possible guidance. Within the scope of the invention it is possible to add additional Provide insulating material web attacking clamping elements that when connecting the insulating plate I1 'with the one already formed Insulation material sheet B additionally fixed this.

From a supply spool 20 is an upright Wire mesh web G according to the direction of arrow P5 with the help a feed roller which can be driven in accordance with the double arrow P6 21 deducted and fed to a straightening device 22. The Straightening device 22 consists of two rows offset from one another arranged straightening rollers 23 and deliverable eccentric rollers 24. With the help of the feed rollers 21, the wire mesh web G gradually fed to a cutting device 25 which essentially a cooperating pair of cutter bars 26 and from the endless wire mesh web G wire mesh mats M separates predetermined length. The cutting device 25 works in the embodiment shown so that it in a so-called gas cut a selectable section from the Wire mesh web G cuts out so that the production line Z-Z fed wire mesh mats spaced apart consequences. In the context of the invention, however, it is also possible Form and control the cutting device 25 such that a separating cut or a trimming cut is carried out.

The wire mesh mat M passes through not shown Guiding devices in the production line Z-Z and is there with Distance and parallel to the insulating material web B using two pairs of conveying elements which can be driven in accordance with the arrows P7, P7 ' 27, 27 'in the production direction P1 step by step the Z-Z production line together with the insulating body web B the downstream processing devices 4, 4 '; 5, 5 'and 6, 6' supplied.

From a mat stack 28 'with the help of a conveyor 29 ', which can be pivoted in accordance with the double arrow P8' is, one after the other wire mesh mats removed and in a Receiving rail 30 stored. With the help of a slide-in device 31 ', the wire mesh mats M' according to the Direction of arrow P9 'successively over a skin pass 32 'of a feed roller which can be driven in accordance with the double arrow P10' 33 'fed. The insertion device 31 'exists for example from a working cylinder, the piston rod is movable according to the double arrow P11 'and with a gripper 34 for gripping the wire mesh mat M ' is. The skin pass device 32 'has staggered arrangements Dressage rollers 35 and eccentric rollers 36. The feed roller 33 'pushes the wire mesh mats M' one after the other gradually into the Z-Z production line, where they are at a distance and parallel to the insulating material web B and together with this with the help of the conveyor element pairs 27, 27 'in the production direction P1 step by step along the Z-Z production line downstream processing devices 4, 4 '; 5, 5 'and 6, 6 'are supplied.

In the bridge wire feeders 4, 4 'are simultaneously from both sides several web wires S, S 'accordingly the arrow directions P12 and P12 'supplied and in horizontal Direction at a selectable angle through the mesh of the Wire mesh mats M, M 'and through the insulating material web B pushed through, the web wires S, S 'with their two Ends on the respective wires L or Q of the wire mesh mats M, M 'with a slight lateral overhang. The web wires S, S 'can be used within the scope of the invention cut off a wire supply using suitable scissors or also as cut-to-length, straightened rods for the bridge wire feeders 4, 4 'are supplied.

With the aid of the pairs of conveying elements 27, 27 ', the wire mesh mats were made M, M 'together with that by means of the transport chain 18 advanced insulation material web B equipped with the bridge wires S, S 'the downstream bridge wire welding devices 6, 6 'supplied, in which the web wires S, S' each with the corresponding wires L or Q of the wire mesh mats M, M ' be welded. The grid body H thus formed together with Isolierkörperbahn B is using two corresponding to the Direction of arrow P13, P13 'drivable conveyor element pairs 37, 37 'fed to the downstream trimming devices 6, 6', in which the wires L or Q of the wire mesh mats M, M 'protruding bridge wire protrusions are cut off flush.

With the help of the pairs of conveying elements 37, 37 ', the grid body H together with the insulating material web B of the cutting device 7 fed. The cutting device 7 separates from the insulating material web B the insulating body K in selectable Length and has at least one driven by cutting drive 38 Cutting disc 39 on. To increase the cutting performance can use a further cutting disc 39 'including drive 37' become. The cutting device 7 becomes synchronous when cutting with the feed movements of the conveyor element pairs 27, 27 'and 37, 37 'moved according to the production direction P1 and after the cut is returned to the starting position, whereby these movements take place according to the double arrow P14. The Drive into the cutting position in the corresponding retraction from the cutting position follows the double arrow P15. The length of the insulating body K can be within the Invention correspond exactly to the length of the wire mesh mats M, M ', so that the cutting device 7 in a so-called alley cut a corresponding piece from the insulating material web B must cut out. However, it has proven to be advantageous the insulating body K somewhat over the wire mesh mats M, M ' protrude, which when using the components P almost continuous insulation in the components P formed walls is reached.

The finished component P is made by one with one trained gripper 40 provided conveyor 41 along the production line Z-Z fed to a cross conveyor 42. The conveyor 41 can, for example, from a working cylinder exist, the piston rod according to the double arrow P16 is movable. The cross conveyor 42 pushes the finished components P according to the direction of the arrow P17 from the production line Z-Z. The cross conveyor 42 consists of, for example two working cylinders, the piston rods of which Double arrow P18 movable and each with a push-off plate 43 are provided.

2 is the inlet area of a further exemplary embodiment a system according to the invention schematically shown. According to this embodiment, insulating plates are used I2 for use compared to that in FIG. 1 Insulating plates I1, I1 'described have flat end faces E. The supply of insulation panels I2 to the production line Z-Z on the conveyor belt 12 takes place via the insertion device 9. To create an endless sheet of insulating material B is the insulating plate I2 'by hot welding using a heating device 44 connected to the insulating material web B. The Heating device 44 consists essentially of a heating plate 45 and a heating transformer for heating the heating plate 45 46th

The endless insulating material web B is made in the following way generated: The insulating plate located on the conveyor belt 12 I2 'becomes corresponding with the help of the feed device 16 the arrow P1 until the insulating plate I2 'on the end face of the insulating material web B abuts heating plate 45. The heating plate 45 is then with the help of the heating transformer 46 heated up until the adjacent end faces of the insulating material web B and the insulating plate I2 'are softened. The hot plate 45 is then in the corresponding arrow direction of the Double arrow P19 quickly from the space between the insulating plate I2 'and the insulating material web B pulled out and the insulating plate I2 'accordingly using the feed device 16 the production direction P1 slightly advanced to the pressed heated end faces against each other and thus the Insulation plate I2 'to be welded to the insulation material web B. and thus to connect positively and non-positively. Because the insulating material web B during the connection process through the conveyor belt 12 step by step, in time with the entire production plant the production direction P1 is conveyed further the heater 44 also during heating step by step according to the corresponding arrow direction of the double arrow P20 moves and after pulling out the heating plate 45 in the corresponding opposite direction of the double arrow P20 in moved back to the starting position.

Within the scope of the invention it is possible, as shown in FIG. 2, the cutting device 7 for severing the insulating material web B immediately behind the heater 44 and before feeding the wire mesh mats M, M 'into the production line To arrange Z-Z. Since the cutting device 7 also when cutting the insulating material web B through the Conveyor chain 18 gradually in time with the entire production plant forwarded according to the production direction P1 becomes, the cutter 7 during cutting also step by step according to the direction of the arrow of the double arrow P14 and after exiting the Section in the corresponding opposite direction of the double arrow P14 moved back to the starting position. The conveyor chain 18 promotes the insulating bodies separated from the insulating material web B. K corresponding to the production direction P1 in the following Processing devices of the plant.

Since the conveyor chain 18 is not in the movement paths of the Heating device 44 and the cutting device 7 may suffice, the insulating material web B in this area of at least two support elements 47 supported by means of a working cylinder 48 according to the double arrow P21 from the trajectory the heater 44 and the cutter 7 can be moved.

Within the scope of the invention it is possible, as in FIG. 2 shown, two supply spools 20, 20 'with wire mesh webs G, G 'to provide the wire mesh mats M, M'. The corresponding elements have the same reference numbers on, each with or without an apostrophe are.

3 is the inlet area of a further exemplary embodiment a system according to the invention schematically shown. According to this embodiment also arrive the insulating plates I2 already described in FIG Application. The supply of the insulating plates 12 in the production line Z-Z on the conveyor belt 12 takes place via the insertion device 9. To create an endless sheet of insulating material B is the insulating plate I2 'by gluing with the help of an adhesive device 49 connected to the insulating material web B. The Gluing device 49 has a spray nozzle 50 together with a storage container that is filled with a suitable adhesive. The glue must be suitable for gluing the material of the insulation panels I2 and be tailored to the production speed Possess drying time to ensure a safe connection of the Insulation plate I2 'to ensure with the insulating material web B. The adhesive device 49 is in accordance with the double arrow P22 can be moved in the horizontal direction and in the vertical direction. For spraying the adhesive onto the end face E of the insulating plate I2 becomes the gluing device 49 corresponding to these Movement directions moved. To apply the glue too accelerate, several adhesive devices can also within the scope of the invention 49 can be used simultaneously. As part of the invention it is also possible to use several insulating plates I2 spray with glue at the same time.

The endless insulating material web B is made in the following way generated: Immediately before the insulation plate I2 is fed into the Production line Z-Z becomes an end face E of the insulating plate I2 with adhesive. The insulation plate I2 is with the help of Feed device 1 initially according to the direction of arrow P2 advanced into the Z-Z production line and on the conveyor belt 12 filed. Then the insulating plate I2 'with the help the feed device 16 according to the production direction P1 slightly advanced around the glued face the insulating plate I2 'against the end face of the insulating material B to press and thus the insulating plate I2 ' to connect the insulating material web B.

3 is another embodiment of a Cutting device 7 for separating the insulating body K from the Isolierstoffbahn B shown. The cutting device 7 has a straight guide slide 51, which corresponds to the Double arrow P14 is slidable along a rail 52, wherein the movement in the production direction P1 synchronously with the Insulation material web B is fed. On the straight guide slide 51, a cutting wire 53 is attached, the corresponding the double arrow P23 can be moved transversely to the insulating material web B. and can be heated using a heating transformer 54. For separating the insulating body K from the insulating material web B is the heated cutting wire 53 accordingly by the Insulating material web B moves and reaches the dashed line in FIG. 3 drawn position. After the cut, the straight guide slide 51 together with cutting wire 53 in its starting position moved back.

In the context of the invention, it is possible to shown cutting device 7 by the one described above To replace the cutting device, i.e. the one described above Arrange the cutting device after the trimming devices 6, 6 '.

Within the scope of the invention it is possible, as in FIG. 3 shown, two mat stacks 28, 28 'with wire mesh mats M, M 'to be provided. The corresponding elements point here the same reference numbers, each with or without an apostrophe are provided.

It is understood that the illustrated embodiments various within the scope of the general inventive concept, especially with regard to the design and execution of devices for connecting the insulating plates for Formation of an endless insulating material web can be modified can. When using appropriate adhesives, both the face of the insulating plate as well as the end The end face of the insulating material web can be provided with adhesive.

Furthermore, it is possible within the scope of the invention, a or both of the flat end faces of the insulating plates to be connected to be provided with a self-adhesive film. The Foil can already be attached during the manufacture of the insulation panels be and is conveniently by a removable Protected film.

Furthermore, it is possible within the scope of the invention that tongue and groove end face of the insulating plates additionally provided with an adhesive to ensure a secure connection to ensure the insulation plates.

The end faces adjacent to form the insulating material web the insulating plates can also within the scope of the invention with other positively and non-positively interacting clamping connection elements be provided, for example, dovetailed are trained.

Furthermore, it is possible within the scope of the invention, others Cutting method and devices for separating the insulating body from the insulating material web to use. This procedure and devices must match the material properties of the Insulating materials must be matched and ensure that the Cut results in smooth edges and the material of the Insulating body is not impaired in its properties, for example, is melted down.

Claims (14)

1. Method for continuous production of construction elements (P), in which two parallel, flat wire mesh mats (14, 14') consisting of longitudinal and transverse wires (L; Q) , crossing one another and welded together at the crossing points, are pushed along in a production line (Z-Z) and an insulating body (K), which is severed from an continuous connected length of insulating material (B) pushed forward, is introduced between the wire mesh mats (M, M'), whereupon the straight web wires (S, S') are guided through the insulating body (K) and are welded to the wire mesh mats (M, M') by their ends, so they are held at a predetermined mutual distance, characterised in that to produce continuous connected length of insulating material (B) the insulating plates (I1, I1'; I2, I2') are conveyed individually and in succession into the production line (Z-Z) and are moved relative to one another in their longitudinal direction (P1), whereby the front faces (N, F; E) of the adjacent insulating plates (I1, I1') are connected to one another by positive and non-positive locking to form the length of insulating material (B).
2. Method according to claim 1, characterised in that to produce the continuous, connected length of insulating material (B) the insulating plates (I1, I1') are connected to one another with their front faces (N, F) in form and force-locking manner by clamping.
3. Method according to claim 2, characterised in that the front faces (N, F) are connected to one another in a form and force-locking manner by a groove and spring-clip connection.
4. Method according to claims, 2 or 3, characterised in that the front faces (N, F) are provided with an adhesive.
5. Method according to claim 1, characterised in that insulating plates (I2, I2') with flat front faces (E) are used and in that to produce the continuous, connected length of insulating material (B) an adhesive is applied to at least one front face (E) of adjacent insulating plates (I2, I2') or the front face is provided with a self-adhesive foil.
6. Method according to claim 1, characterised in that insulating plates (I2, I2') with flat front faces (E) are used and in that to produce the continuous, connected length of insulating material (B) the front face (E) of one insulating plate (I2') and the end front face of the length of insulating material (B) are jointly heated and connected by welding.
7. Installation for carrying out the method according to one of claims 1 to 6, with two storage magazines (20) for lengths of wire mesh (G, G'), aligning and cutting devices (22; 25) for each length of wire mesh (G, G'), a feed device (1) for insulating plates (I1, I1'; I2, I2'), a cutting device (7) for severing an insulating body (K) from the length of insulating material (B), at least one group of web wire storage spools together with associated web wire feed and cutting devices (4, 4'), web wire welding devices (5, 5'), web wire edge trimming devices (6, 6') and several conveying devices (18; 27, 27'; 37, 37') coupled to one another for the insulating body (K), the lengths of wire mesh (G, G') or wire mesh mats (M, M'), the mesh body (H) and the construction element (P) , characterised in that a forward feed device (16) for moving the insulating plates (I1, I1'; I2, I2') relative to a length of insulating material (B) for the purpose of forming a positive and non-positive connection between the insulating plates (I1, I1', I2, I2') is provided and in that the cutting device (7) is movable in parallel to the production line (Z-Z) .
8. Installation according to claim 7, characterised in that the cutting device (7) has at least one drivable cutting disc (39) which is movable transversely and vertically with respect to the direction (P1) of production.
9. Installation according to claim 8, characterised in that the cutting device (7) has a cutting wire (53) which is movable transversely to the length of insulating material (B) and can be heated by means of a filament transformer (54).
10. Installation according to one of claims 7 to 9, characterised in that to produce the length of insulating material (B) a heating plate (45) is provided, by which the front face (E) of one insulating plate (I2') and the end front face of the length of insulating material (B) can be jointly heated.
11. Installation according to one of claims 7 to 9, characterised in that to produce the length of insulating material (B) at least one adhesive device (49), movable in the horizontal and vertical direction, is provided, with which at least one front face (E) of adjacent insulating plates (I2') can be provided with a layer of adhesive.
12. Installation according to one of claims 7 to 11, characterised in that the cutting device (7) is arranged in the production direction behind the trimming devices (6, 6').
13. Installation according to one of claims 7 to 11, characterised in that the cutting device (7) is arranged in front of the conveying device (18) for the insulating body (K) and that support elements (47) moveable into the forward feed path of the length of insulating material (B) are provided in the region between the feed device (12) for the insulating plates (I1', I2') and the conveying device (18) for the insulating body (K).
14. Installation according to one of claims 7 to 13, characterised in that a transporter (29, 29') is provided for the removal of wire mesh mats (M, M') already cut into lengths from at least one stack of mats (28, 28') and an insertion device (31, 31') for inserting the wire mesh mats (M, M') into a dressing device (32, 32') and a drivable conveyor roller (33, 33') for inserting the aligned wire mesh mats (M, M') into the production line (Z-Z) are provided, wherein the conveyor roller (33, 33') is coupled to the conveying device (12) for the length of insulating material (B) and the insulating body (K), to the conveying devices (27, 27') for the wire mesh mats (M, M'), to the conveying devices (37, 37') for the mesh body (H) and if applicable to the conveyor roller (21, 21') for a length of wire mesh (G, G').

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