RU2416471C2 - Device and method of boards sorting - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: boards (14) are fed to sorting line (3) consisting of inlet conveyor (4) and sorting conveyors (5, 5.1, 5.2, 5.n). For automatic boards sorting, pushing lever (6) is used to push boards to line (8) in compliance with preselected sequence so that boards pass by endless continuous chain (13) and are pushed by cylinder (11) down as-sorted (14.1) onto cross conveyor (15) for them to be transferred onto adjacent sorting line (3.1). Workers (10) manually sort boards and push them onto line (9) to move by endless continuous chains (13.1, 13.2), (13.3), (13.n) so that the boards are pushed down by one of cylinders (12), (12.1), (12.2), (12.n) as manually sorted boards (14.2) on appropriate cross conveyor (16), (16.1), (16.2), (16.n) for them to be transferred to storage zone. In compliance with this invention, proposed device may consist of several parallel sorting lines.

EFFECT: simplified sorting.

17 cl, 7 dwg

Description

The object of the invention is a device and method for sorting boards, or, more precisely, a sorting line with a feed conveyor for mechanically and / or manually sorting boards from circulation, whereby the boards move at high speed; the parameters and criteria are respectively determined in advance, and therefore the boards sorted in this way are taken out of circulation in the places intended for this purpose, while the other boards are redirected and accordingly move to other conveyors, lines and storage areas.

In accordance with the international patent classification, this invention relates to subclasses B07C 3/00 and B07C 5/00, and in addition to subclasses B65G 47/52, B65H 29/58, B65H 29/68.

The technical problem solved by this invention is to develop such a device design that will allow the automatic sorting and appropriate separation of the already processed boards on the basis of parameters determined in advance, for example, on the basis of an odd or even number, etc., due to which boards will be sorted in places determined for this purpose; at the same time, it will be possible to manually sort the boards due to their quality or some other additionally selectable criterion, the correspondence of which can be determined visually; this will be carried out at a high speed of movement of a large number of boards at the place of entry into the device and during their movement through the device or device.

There are several fairly similar solutions for sorting materials and objects of different types, respectively. A device for sorting flat, flexible or rigid objects is known from EP 1055461. These objects move on a conveyor, which is in contact with rotating cylinders built into oscillating levers with the possibility of movement. When an item arrives at some raised cylinder, it slides into the channel under that cylinder. One cylinder belongs to each cylinder, as a result of which it is possible to sort objects into selectable channels. This solution cannot be used to sort a large number of longer workpieces, such as boards that move at high speed.

Another solution is known from DE 1453313 and is based on a conveyor system. The workpiece moves on a linear conveyor to the conveyor, which is located above the linear conveyor. When a workpiece falls under this conveyor, it has two options, depending on the position of the shutter in front of the workpiece. If the shutter is in the raised position, the workpiece falls on the conveyor located below, as a result of which it is separated from the workpiece flow. If the shutter is horizontal, the workpiece continues to move along the same linear conveyor. This solution is not suitable for sorting a larger number of longer workpieces, such as boards that move at high speed.

The following known solution related to a sorting device is known from document PCT / WO 2005/003003. Objects of different shapes move on a conveyor, over which movable shutters are placed at some distances. Which of the channels will be sorted into a single item depends on the position of the individual dampers. This solution is not suitable for sorting a larger number of longer workpieces, such as boards that move at high speed.

A document for sorting wood is known from AT 296155; this device consists of fixed and movable conveyors, corresponding adjustable dampers and collectors. On one stationary conveyor, a bunch of wood billets moves, which are then sorted one after another by means of a movable lever, which directs them to one of the corresponding transportable conveyors. Which of the collectors a single blank will fall into depends on the position of the individual dampers. The weakness and disadvantage of this known solution is that it is very complex and does not guarantee the sorting of longer workpieces, for example, boards that move at high speed.

From the document US 3791518 known sorting conveyor, which is intended for sorting round billets entering the worm conveyor in a suitable appropriate channel, which is part of the device. For this purpose, adjustable casing on roller bearings is used. This solution is not suitable for sorting a larger number of longer workpieces, such as boards that move at high speed.

From document AT 408082, a device is known for sorting individual workpieces from a bundle or bag that or which moves on a conveyor. In a preferred embodiment, the essence is to separate the last board in a package of vertically standing boards in a designated place. The weak point and disadvantage of the known solution is that it is very complex and does not provide sorting of boards on the basis of visual criteria, for example, quality or defects, since it is impossible to consider each board because they are in the package. In addition, its disadvantage is that the sorting of boards can be carried out only in the same place and in the same direction. In addition, this solution does not make it possible to sort a larger number of boards that move at high speed.

A general characteristic of the described known solutions is that they all provide for the presence of shutters of various designs, the function of which is to redirect objects from the conveyor to various channels that are separated from each other. The problem that remains unresolved is mainly related to the fact that these solutions can only be used for automatic sorting and separation of shorter — preferably, preferred — objects that, as a rule, move at a low speed, which makes it possible to sort only a smaller number items within a specific unit of time.

In accordance with the invention, the problem is solved by using a device and method for automatically and manually sorting more boards, preferably of the same length, which move at high speed; the device consists of a selectable number of sorting lines consisting of a braking conveyor, an input conveyor and sorting conveyors with adjustable endless conveyor chains and corresponding pushing levers and pushing cylinders, as a result of which transverse conveyors are located between the longitudinal sorting lines and below them for transporting the separated boards to other lines or other storage areas. A more detailed description of the invention will be given in connection with a preferred embodiment and drawings, which show the following:

figure 1 - device in accordance with the invention in plan view;

figure 2 - sorting line in side view and in longitudinal section aa;

figure 3 - detail of the transition zone between the inlet conveyor and the sorting conveyor in plan view;

figure 4 - sorting conveyor in cross section bb with a schematic representation of the position in which the board moves along this conveyor;

5 is a sorting conveyor in cross section CC with a schematic representation of the removal of the sorted board before this board falls on the corresponding transverse conveyor;

6 is a detail of an automatic travel lever in a plan view;

7 is a detail of the leveling arm in a plan view.

In the embodiment of FIG. 1, the board sorting device consists of a sorting line assembly 3 with two braking conveyors 2 and 18 and an additional sorting line assembly 3.1 with sorting conveyors 17 and 19. Intermediate transverse conveyors 15, 16 are placed between the sorting lines 3 and 3.1. , 16.1, 16.3-16.n. In some other embodiment, the device according to the invention may consist of only one of sorting lines — 3 or 3.1, or more sorting lines 3, 3.1-3.n, which are preferably parallel to each other and are located at a small distance from each other.

Before entering the sorting line 3 and at its inlet conveyor 4, respectively, there is a braking conveyor 2, and in front of it is a feeding conveyor 1. The braking conveyor 2 and the feeding conveyor 1 are arranged in such a way that their longitudinal axes form an optionally set internal angle α, which depends on the input speed of the boards 14, as well as their length and width. The braking conveyor 2 has an adjustable on / off shutter 36 located above the conveyor zone. The gap and the radial angle between the two positions, respectively, can be determined by choice, depending on a predetermined angle α and the speed of movement of the input boards 14.

As already described, the sorting line 3 is located on the output side of the braking conveyor 2 and along it, so that their longitudinal axes cover a mutual internal angle, which is determined by choice and preferably less than or equal to 90 °.

In connection with the above described embodiment, it should be noted that the sorting line 3, when viewed in the direction in which the boards 14 are moving, consists of an input conveyor 4, sorting conveyors 5, 5.1 and 5.2 and transverse conveyors 15, 16, 16.1, 16.3, as well as the corresponding braking conveyors 17, 18, 19. This is shown in figure 1.

Typically, the inlet conveyor 4 and the sorting conveyors 5, 5.1 and 5.2 are located one after the other or one after the other, respectively, so that they are arranged sequentially along the major axis of the sorting line 3, as a result of which they guarantee a smooth flow of boards 14 and - at some point later - automatically sorted boards 14.1 and manually sorted boards 14.2 on sorting line 3.

Along the inlet conveyor 4, the endless conveyor chains 37, 38 and 39 are arranged parallel to each other at a selectable distance from each other and are attached to the frame 21. To the inlet conveyor 4 or to one of its sides - immediately pushing the front of the inlet conveyor 4 a lever 6, which embodies the running movement, usually carried out automatically.

Along the sorting conveyor 5, the endless conveyor chains 40, 41 and 42 are arranged parallel to each other at a selectable distance from each other and are attached to the frame 21.1. The conveyor chain 40 is attached to the frame 21.1 with the possibility of movement so that it can be moved horizontally in the transverse direction, while the conveyor chains 41 and 42, as a rule, are fixed to the frame 21.1 motionless. The same can be said about the endless conveyor chains 45, 46 and 47, which are located along the sorting conveyor 5.1. They are also parallel to each other at a selectable distance from each other and attached to the frame 21.2 so that there is the possibility of horizontal movement of the conveyor chain 45 in the transverse direction, while the conveyor chains 46 and 47, as a rule, are fixed. The same can be said of the endless conveyor chains 48, 49 and 50, which are located along the sorting conveyor 5.2 in parallel, as a result of which the endless conveyor chain 48 is able to move horizontally in the transverse direction. At the end of the sorting conveyor 5.1 and on its side is the leveling lever 43.

The output conveyor 22 also has several parallel endless conveyor chains, which, however, will not be specifically marked.

Considering the design of the entire sorting line 3, we note that, as a rule, all the endless conveyor chains 37, 38, 39, 40, 41, 42, 45, 46, 47 are in the same horizontal plane, which is located slightly above the pushing cylinders 11, 12, 12.1, 12.2, 12.n. In addition, as a rule, within the sorting line 3, the movable endless conveyor chains 40, 45 and 48 are arranged or adjusted so that they are arranged sequentially and one after the other exactly on the same longitudinal straight line. This means that the distance between the conveyor chain 45 and the adjacent conveyor chain 46 is exactly the same as the distance between the conveyor chain 40 and the conveyor chain 41 and the distance between the conveyor chain 48 and the conveyor chain 49. This same distance can be determined by choice, and it depends on the length of the boards 14, which come from the feed conveyor 1 and through the braking conveyor 2 to the sorting line 3; the regulation of this uniform distance is guaranteed by the horizontalness and the design of the endless conveyor belts 40, 45 and 48, made with the possibility of movement in the transverse direction.

In connection with the embodiment of FIG. 1, the transverse conveyor 15 is located in the transition zone between the inlet conveyor 4 and the sorting conveyor 5, the transverse conveyor 16 is located between the sorting conveyors 5 and 5.1, the transverse conveyor 16.1 is located between the sorting conveyors 5.1 and 5.2, and the transverse conveyor 16.3 is located between the sorting conveyor 5.2 and the output conveyor 22. The transverse conveyors 15, 16, 16.1 and 16.3 are located slightly below the level of the sorting plane ransporterov 5, 5.1 and 5.2. This is presented in figure 1 and figure 2. In connection with some other embodiment, note that they may also have a different design.

In the area above the transverse conveyor 15 there is a pushing cylinder 11 and an endless flow chain 13, each of these components is on its own side of the sorting conveyor 5 and in the same plane. Above the transverse conveyor 16 are a pushing cylinder 12 and an endless flow chain 13.1, each of these components is on its own side of the sorting conveyor 5.1 and in the same plane. Above the transverse conveyor 16.1 there is a pushing cylinder 12.1 and an endless flow chain 13.2, each of these components is on its side of the sorting conveyor 5.2 and in the same plane, while above the transverse conveyor 16.3 there are a pushing cylinder 12.2 and an endless flow chain 13.3. Thus, we can say that the endless flow chains 13, 13.1, 13.2, 13.3 can be located on either side of the sorting line 3. In this embodiment, the endless flow chain 13 is located at the adjacent endless conveyor chain 42 and between lines 8 and 9, while the endless flow chain 13.1 is located at the endless conveyor chains 42 and 45, respectively; in addition, the endless flow chain 13.2 is located at the endless conveyor chains 47 and 50, respectively, and the endless flow chain 13.3 is located at the endless conveyor chains 50. In some other embodiment, the endless flow chains 13, 13.1, 13.2, 13.3 can be placed and installed by to another.

As a rule, the endless flow chains 13, 13.1, 13.2, 13.3 are slightly shorter than the endless conveyor chains 37, 38, 39, as well as the endless conveyor chains 40, 41, 41, as well as 45, 46, 47 and 48, 49, fifty.

In addition, we can also say that the pushing cylinders 11, 12, 12.1 and 12.2, as a rule, are located slightly below the level of the corresponding working surfaces, i.e. adjacent endless conveyor chains 40, 42, 45, 48. The above components are presented in figure 1 and figure 2, and partially also in figure 3.

The already mentioned transverse conveyors 15, 16, 16.1, 16.2 and 16.3 are located under a selectable, preferably right angle to the longitudinal axis of the sorting line 3, and therefore to the longitudinal axis of the aforementioned joints of its components; thus, they cross-connect the corresponding connections of the main sorting line 3 with the corresponding connections of the additional sorting line 3.1, which is parallel to the sorting line 3. As already mentioned, the device according to the invention may, in some other embodiment, comprise a selectable number of sorting lines 3, 3.1 and / or 3.n, as well as a selectable number of respective transverse conveyors 15, 16, 16.1, 16.3 and / or 16.n, which are served from one side or on the other hand determined by the choice of the number of workers 10.

In the embodiment of FIGS. 1 and 2, at least one travel pushing lever 6 is located on the longitudinal side of the inlet conveyor 4 of the sorting line 3, while at least one running pushing lever 43 is located on the longitudinal side of the inlet conveyor 5.2. In connection with some other embodiment, it can be said that the input conveyor 4 and the sorting conveyors 5, 5.1, 5.2 and 5.n can be equipped with a selectable number of running pushing levers 6-6.n and a selectable number of leveling levers 43- 43.n, respectively, which are attached to them on at least one side or on both sides. Fasteners, which may have a selectable design, should guarantee their movement around the pivot point of the lever. Running pushing lever is shown in Fig.6.

Behind the input conveyor 4 of the sorting line 3 in the direction of movement of the boards 14 and the automatically sorted boards 14.1, respectively, there is a sorting conveyor 5, which has at its entrance a pushing cylinder 11 with a drive located on one longitudinal axis so that it can rotate, while opposite the sorting conveyor 5, there is an endless flow chain 13 that connects the inlet conveyor 4 with the sorting conveyor 5. The longitudinal axis of the pushing cylinder 11 is parallel to the longitudinal the axis of the sorting line 3 and sorting conveyor 5, respectively. The drive of the pushing cylinder 11 is not specifically designated, since it is a conventional drive of the corresponding design. Slightly lower than the pushing cylinder 11 and the endless flow chain 13 is a transverse conveyor 15, which is preferably perpendicular to the longitudinal axis of the sorting conveyor 5 and which has an optionally determined design and length.

At the opposite end of the sorting conveyor 5, a movable pushing cylinder 12 is attached to a line located on its opposite side; a transverse conveyor 16 is located under the pushing cylinder 12, preferably at a right angle to the longitudinal axis of the sorting line 3 and the sorting conveyor 5, respectively. Opposite the pushing cylinder 12 is an endless flow chain 13.1, which connects the sorting conveyors 5 and 5.1.

Behind the inlet conveyor 5, a sorting conveyor 5.1 is located, under which there is a transverse conveyor 16.1, and above it there is a pusher cylinder 12.1 rotatably movable and an endless flow chain 13.2, each of these components being on the side intended for it and between the sorting conveyors 5 and 5.1.

Behind the input conveyor 5.1, there is a sorting conveyor 5.2, under which there is a transverse conveyor 16.3, and above it there is a pusher cylinder 12.2 arranged with the possibility of pivoting and an endless flow chain 13.3, each of these components being on the side intended for it and between the sorting conveyors 5.1 and 5.2.

For the above reasons, it can be said that the distance between the pushing cylinders 11, 12, 12.1 and 12.2 and to the endless flow chains 13, 13.1, 13.2 and 13.3 belonging to them, which are located opposite them, is usually shorter than the length of the boards 14, which are sorted and sorted respectively on sorting line 3. The same can be said of all other sorting lines 3.1-3.n.

As is obvious from figure 1, at the end of the sorting conveyor 5.2 - on its side - there is a leveling lever 43; this leveling arm 43 is shown in FIG.

Behind the sorting conveyor 5.2, there is an output conveyor 22, which terminates the sorting line 3, and it may have a design determined by choice.

In some other exemplary embodiment of the sorting line 3, which is not shown, the transverse conveyors 15, 16, 16.1, 16.3-16.n can be positioned at an angle to the sorting conveyors 5, 5.1, 5.2-5.n, which is larger or smaller than the right angle . Likewise, the pushing cylinders 11, 12, 12.1 and 12.2-12.n can be positioned in selectable places within the selectable side of the sorting line 3; the same can be said of the endless flow chains 13, 13.1, 13.2, 13.3-13.n and the pushing levers 6-6.n, as well as the leveling levers 43-43.n.

From figure 2, which shows a side view of the sorting line 3, it is obvious that the working and end zones of the extreme segments at the input of the input conveyor 4 and at the output of the output conveyor 22 are designed horizontal and parallel to each other, as a result of which the latter is somewhat lower than the first. The working areas of the sorting conveyors 5, 5.1 and 5.2 are arranged in series, and they fall at selectable angles to the horizontal working area of the output conveyor 22. This means that the working areas of the inlet conveyor 4, sorting conveyors 5, 5.1 and 5.2 and the output conveyor 22 are in different planes, the distance between which is determined by choice, and these planes are lowered to the output conveyor 22 at angles determined by choice, as a result of which they end at the contact points, and therefore they azuyut set of successive slopes with different lengths and angles of the individual segments.

Figure 1 presents an additional sorting line 3.1, which is located parallel to the main sorting line 3 and at a small distance from it, and the conveyor zones of these lines lie in the same plane or in different planes. Therefore, the rule that sorting line 3 has as many additional sorting lines 3.1-3.n as necessary to satisfy the requirements of sorting boards, including the number of input boards 14 per unit time, input speed and speed of movement of the boards 14, is applicable. as well as boards 14.1 and 14.2, respectively, and in addition to this, also the number and level of visual sorting criteria such as machining quality, deformation, dimensions, even or odd number, etc.

Sorting lines 3 and 3.1 are logistically connected to each other by means of transverse conveyors 15, 16, 16.1, 16.2 and 16.3, located between them and at a certain distance from each other; they may be parallel or located at selectable angles between them. As a result, between the transverse conveyor 15 and the inlet conveyor 4 of the sorting line 3.1, there is a braking conveyor 16, which, like the braking conveyor in front of the sorting line 3, is offset by an angle α from the longitudinal axis of the transverse conveyor 15. The same can be said about the braking conveyor 18 between transverse conveyor 16.2 and sorting conveyor 5.1 sorting line 3 and the braking conveyor 19 between the transverse conveyor 16.3 and sorting conveyor 15.2 sorting line 3.1.

Like sorting line 3, additional sorting line 3.1 and - possibly other additional sorting lines 3.n, as a rule, consist of an input conveyor 4 with a pushing lever 20, a sorting conveyor 5 and a sorting conveyor 5.1 with a leveling lever 44 and an output end conveyor 22, which are located in the above sequence. In an identical manner, a pushing cylinder 12 and an endless flow chain 13.4 are arranged above the transverse conveyor 16, each of these components being constructed on one side of the sorting conveyor 5; in addition, a pushing cylinder 12.1 and an endless flow chain 13.5 are located above the transverse conveyor 16.1, and a pushing cylinder 12.3 and an endless flow chain 13.6 are located above the transverse conveyor 16.2; in some other embodiment, they may be located somewhat differently along one or the other side of the sorting line 3.1. All of the above in connection with sorting line 3 is also applicable for sorting line 3.1 and for every possible additional sorting line 3.n, as a result of which this will not be described again.

The pushing travel arms 6 and 20, the selectable amount of which can be located on the selectable sides of the input conveyors 4 of sorting lines 3, 3.1 or 3.n, are designed in such a way that the travel action can be adjusted automatically, as shown in Fig.6. The leveling levers 43 and 44, the optionally determined quantity of which can likewise be located on the optionally determined sides of the sorting conveyors 5.1 and 5.2, respectively, are designed in such a way that the running action can be adjusted manually; they are presented in Fig.7.

In some other embodiments, the pushing arms 6, 20 and the leveling arms 43, 44 can be formed on other components of the sorting lines 3, 3.1 or 3.n, for example, on the sorting conveyors 5, etc.

Figure 6 shows that the automatic travel levers 6 and 20 consist of a housing 26 to which a drive 23 and a tension wheel 24 are attached, whereby they are rotatable; they are surrounded by a multi-linear chain 25 and are interconnected with it. The housing 26 is articulated for movement with the pushing cylinder 27 at the movable clamping point 29, while the pushing cylinder 26 is attached to the inlet conveyor 4 via the movable clamping point 28. Their lateral deviation in the range of the angle "γ" represents the angle by which the multi-line circuit 25 is shifted from the edge of the input conveyor 4, to which it is attached with the possibility of movement.

The leveling levers 43 and 44 consist of a housing 33 to which a drive 30 and a tension wheel 31 are attached, as a result of which they are rotatable and both are surrounded by a multi-line chain 32 and interconnected with it. A leveling groove 34 is made in the housing 33, which, together with the fastening element 35, makes it possible to manually adjust the angle β; this angle represents the lateral deviation of the multi-line circuit 32 from the sorting conveyor 5.1. This is presented in Fig.7.

As described above, the automatic pushing arms 6 and 20, as well as the leveling arms 43 and 44, can be said that the tension wheels 24 and 31 and the corresponding multi-line chains 25 and 32 have a selectable standard design.

A device for sorting logs in accordance with this invention is preferably constructed as an integral part or part following some other wood processing line, for example, a device for high-speed joining and coupling of boards with each other to produce extremely long wood blanks at high speed, or some other device for preliminary surface treatment or some other processing of extremely long wood workpieces which I cut with a suitable saw camping into smaller pieces for certain wavelengths, such as boards 14, defined by the choice of lengths, which then move in large quantities and at high speed. The device corresponding to this invention is preferably intended for automatic and manual sorting of boards 14 and cutting them into pieces of the same length.

As mentioned above, the board sorting apparatus according to this invention consists of a feed conveyor 1, a braking conveyor 2, a sorting line 3 and an additional sorting line 3.1, which are parallel to each other, and the distance between them is determined by choice; they are connected to each other by transverse conveyors 15, 16, 16.1, 16.2 and 16.3, as well as braking conveyors 17, 18 and 19, so that sorted boards 14.1 and manually sorted boards 14.2 can move between them. This brief description of the device in accordance with the invention is given as an introduction to the description of the method of sorting boards 14, which is given below.

Therefore, the device in accordance with the invention is intended for automatic and manual sorting of the boards 14, as a result of which it becomes possible to automatically sort based on the pushing arms 6-6.n and 20-20.n, respectively, which are attached to the above-described nodes of the sorting lines 3, 3.1 -3.n, while manual sorting is carried out by workers 10 in places defined for this along sorting lines 3, 3.1-3.n, therefore, the number of automatic running push levers 6 and 20 depends mainly on number of sorting lines 14.1 and on the number of sorting lines 3, 3.1-3.n, whereas the number of places determined for manual sorting by workers 10 depends mainly on the throughput of sorting lines 3, 3.1-3.n and type and number of criteria defined for visual sorting or sorting of boards 14.2, which is carried out only on the basis of direct inspection and manual sorting. These criteria and sorting parameters can mainly include the quality of surface treatment of boards 14, their sizes, deformations, etc. Further in this text, as in the description of the device, the boards 14, which will be sorted automatically, will be indicated by 14.1, while the boards 14, which will be sorted manually, will be indicated by 14.2, in order to simplify the understanding of how to sort the boards.

Before the procedure for sorting boards 14, it is necessary to prepare and adjust the sorting line 3 and the additional sorting line 3.1. This is done by adjusting and fixing the distance of the reciprocating movement between the endless conveyor chains 40 and 42 on the sorting conveyor 5; this is guaranteed by the endless conveyor chain 40, which is made with the possibility of horizontal movement in the transverse direction. The size of said reciprocating distance between the conveyor chains 40 and 42 is determined based, for example, on the length of the boards 14 to be sorted.

Similarly, the distance between the endless conveyor chains 45 and 47 on the sorting conveyor 5.1 is adjustable and fixed; the same is also done with respect to the distance of the reciprocating movement between the endless conveyor chains 48 and 50 on the sorting conveyor 5.2.

In connection with all the aforementioned adjustments of the distances of the reciprocating movement, the rule is applied that the distances of the reciprocating movement between the endless conveyor chains 40 and 42, 45 and 47, as well as 48 and 50, in the preferred embodiment, are exactly the same when on the sorting lines 3 sorting boards 14 of approximately the same length.

The preceding description is also applicable for adjusting the distances of the reciprocating movement between the endless conveyor chains 40 and 42, 45 and 47, as well as 48 and 50 on the sorting conveyors 5 and 5.1, respectively, on the sorting line 3.1.

The sorting procedure on the device in accordance with this invention is carried out in such a way that the boards 14 move with the help of the feed conveyor 1 in large numbers and at high speed towards the braking conveyor 2, the function of which is to reduce their extremely high speed to a suitable lower speed and their direction by means of an adjustable damper 36 to the input conveyor 4 of the sorting line 3 so that they arrive at the input conveyor 4 in some direction chnoe position close to a position at a right angle. Due to the still relatively high speed of the boards 14, they are loaded laterally, one behind the other, onto the inlet conveyor 4, and in this position they move on it to the running pushing lever 6. As mentioned above, the hit of the automatic pushing lever 6 depends mainly on the quantity additional sorting lines 3.1-3.n. In the embodiment of FIG. 1, the device in accordance with this invention consists of sorting lines 3 and 3.1, therefore, the automatic pushing lever 6 operates in two working strokes as even-odd. This means that all even-numbered boards 14, which are pushed forward to the line 8 on the sorting conveyor 5 by the pushing lever 6, are then sorted as automatically sorted boards 14.1. Each odd board 14, which is not pushed forward to line 8 by the pushing lever 6 or which remains on line 7 with its smaller end surface, moves further as board 14 to one or more workers 10, which then sort the boards 14 manually as manually sorted boards 14.2 if they do not meet the predefined criteria or if they are not removed for some other reason. This is presented in figure 1 and figure 3. In some other embodiment, the automatically sorted boards 14.1 may also be odd, and manually sorted boards 14.2 in this case are even; quantitative sorting can be prepared in any other way.

When the board 14.1, which was previously axially pushed and graded, arrives at the pushing cylinder 11 between the inlet conveyor 4 and the sorting conveyor 5, it is sorted out from the plank set 14 so that the rotary pushing cylinder 11 pushes it into the transverse conveyor 15 located under him. As a result, one shorter edge of the board 14.1, since it was previously axially offset, falls on the transverse conveyor 15, while the other shorter edge, which is opposite the first, leans against the rotary pushing cylinder 11, which, in the end, pushes the whole the board 14.1 on the transverse conveyor 15. Therefore, it can be said that the automatically sorted dock 14.1 moves due to the pushing cylinder 11 onto the transverse conveyor 15 until its other shorter edge also slides or falls on and whether in the transverse conveyor 15. Therefore, it can also be said that the distance between the endless conveyor belt 40 with the pivoting push cylinder 11 and the endless flow chain 13 should be slightly less than the length of the boards 14, and it should be slightly adjustable under the shorter edge of the board. The same applies for the distances between all other such elements along the entire sorting line 3 and 3.1-3.n, respectively.

Board 14.1 enters with the help of the transverse conveyor 15 to the braking conveyor 17, which reduces the speed of its movement, with which it gets to the input conveyor 4 of an additional parallel sorting line 3.1. Thus, it can be said that the direction of rotation of the pushing cylinder 11 is preferably the same as the direction of movement of the transverse conveyor 15. This description is presented in FIG. 1 and, in part, in FIG. 3.

Boards 14, which are not sorted automatically by the pushing lever 6, move further along line 7 and, using an endless chain of chains 13, to the sorting conveyor 5, where one or more workers 10 are waiting for them, who will take care of manual sorting of the boards 14.2, which will be the boards that do not meet the visual criteria defined in advance, such as quantity, quality and other visually observable criteria. Boards 14 will be sorted so that the workers 10 will manually push them to line 9; as a result, the pushing cylinder 12 will push them into the transverse conveyor 16 below it, by which they will be transported to a certain storage area. This description is presented in FIGS. 4 and 5; in the same way it applies to the aforementioned pushing cylinder 11 with a transverse conveyor 15, and for a pushing cylinder 12.1 with a transverse conveyor 16.1, and for a pushing cylinder 12.1 with a transverse conveyor 16.3 on the sorting line 3. Similarly, the same applies for the pushing cylinders 12, 12.1 and 12.2 and for their respective transverse conveyors 16, 16.1 and 16.2.

Boards 14, which are not manually sorted from sorting conveyors 5 and 5.1 by workers 10, move further along line 7 and using an endless chain 13.1 to sorting conveyor 5.2, from which workers 10 can, if boards 15 do not meet the criteria, sort them in the manner described above , i.e. pushing them to line 8, after which the pushing cylinder 12.1 pushes them like boards 14.2 into the transverse conveyor 16.1, located under it. In exactly the same way, workers 10 sort unsuitable boards 14 also by means of a pushing cylinder 12.2 located above the transverse conveyor 13.3.

At the end of the sorting line 3, the leveling lever 43, which is attached to the sorting conveyor 5.2, guides the boards 14, which were not previously manually sorted by the workers 10, like the boards 14.2 into one or more storage areas based on the already known quantitative sequence.

In some other embodiment, which is not shown, the sequence, location and ratio, i.e. the number of built-in running pushing levers 6-6.n within the sorting line 3 and the number of built-in running pushing levers 20-6.n within the sorting line 3.1 or 3.n can be determined by choice depending on requirements and required criteria. The same applies for pushing cylinders 11, 12, 12.1, 12.2-12.n and for transverse conveyors 15, 16, 16.1, 16.2-16.n.

As described previously, boards 14.1, which are automatically sorted from the sorting line 3 by means of a pushing travel lever 6 based on a predetermined quantitative criterion, fall onto the transverse conveyor 15, along which they move to the braking conveyor 17 located in front of the additional sorting line 3.1, which reduces the speed of their movement and directs them to the input conveyor 4 lines 3.1. The inlet conveyor 4 can also be equipped with a travel pushing lever 20 for further sorting of the boards 14.1 based on a quantitative criterion, as described in connection with sorting line 3. The same applies to leveling lever 44 at the end of additional sorting line 3.1. The procedure for manual sorting of boards 14.2 by workers 10 on sorting conveyors 5 and 5.1 of an additional sorting line 3.1 is identical to the procedure described above for manual sorting on sorting line 3 based on visual criteria.

Claims (17)

1. A device for sorting boards, in relation to which the input conveyor, sorting conveyors and the output conveyor are arranged in series, forming a separate sorting line, characterized in that along at least one side of the sorting line (3), respectively, within each individual sorting conveyor ( 5), respectively (5.1), respectively (5.2), at least one infinite conveyor chain (40), arranged with the possibility of horizontal movement, is located, respectively (45) , respectively (48), moreover, they follow each other in a sequence of lines and each of them is itself made with the possibility of linear movement in the transverse direction, and at the same time, you can adjust and fix the distance from them to infinite conveyor chains by choice (41, 42), respectively (46, 47), respectively (49, 50), which are parallel to them and fixed motionless, and at least one pushing cylinder (11) and at least one are located within the sorting line (3) above the transverse conveyor (15) infinite n exact circuit (13); moreover, at least one pushing cylinder (12) and at least one endless flow chain (13.1) are located above the transverse conveyor (16) within the sorting line (3), and there are at least one pushing cylinder within the sorting line (3.1) a cylinder (12) and at least one infinite flow chain (13.4), with at least one pushing cylinder (12.1) and at least one infinite flow chain (13.2) above the transverse conveyor (16.1) within the sorting line (3) ), and within the sorting line (3.1), at least one pushing cylinder (12.1) and at least one infinite flow chain (13.5) are false; moreover, at least one pushing cylinder (12.3) and at least one infinite flow chain (13.6) are located above the transverse conveyor (16.2) within the sorting line (3.1); moreover, at least one pushing cylinder (12.2) and at least one infinite flow chain (13.3) are located above the transverse conveyor (16.3) within the sorting line (3); moreover, on the sorting line (3), the pushing cylinders (11, 12, 12.1, 12.2) are made on one side, and the infinite flow chains (13, 13.1, 13.2, 13.3) are made on the opposite side of the corresponding sorting conveyor (5, 5.1, 5.2) , the same applies to pushing cylinders (12, 12.1, 12.3) and endless flow chains (13.4, 13.5, 13.6) on a parallel sorting line (3.1) located linearly opposite each other and at a distance determined by choice, as a rule that is shorter than the length of the boards (14), while the pushing cylinders (11), (12) , (12.1), (12.2), (12.3) are located slightly below the level of the corresponding nodes of the infinite conveyor chains (37, 38, 39), respectively (40, 41, 42), respectively (45, 46, 47), respectively (48, 49, 50); moreover, the endless flow chain is located at the adjacent endless conveyor chain 42 and between lines (8) and (9); moreover, the infinite flow chain (13.1) is located at adjacent infinite conveyor chains (40, 45) and between them; moreover, the infinite flow chain (13.2) is located at adjacent infinite conveyor chains (47, 50) and between them; moreover, an infinite flow chain (13.3) is located at a neighboring infinite conveyor chain (50). 2. A device for sorting boards according to claim 1, characterized in that the transport zones of the input conveyor (4), sorting conveyors (5, 5.1, 5.2) and the output conveyor (22), respectively, are preferably located at different levels of height and in different planes , which can be horizontal or inclined at an optionally determined angle to the corresponding frame (21), respectively, frame (21.1), respectively, frame (21.2), respectively, frame (21.3). 3. A device for sorting boards according to claim 1, characterized in that at least one running pushing lever (6) is attached to the input conveyor (4) of the sorting line (3), the multi-line chain (25) of which makes a swinging movement on the housing ( 26) within the limits of the angle determined by choice (γ). 4. A device for sorting boards according to claim 1, characterized in that at least one leveling lever (43) is attached to the sorting conveyor (5.2), which is located in front of the output conveyor (22), relative to which the position of the multi-line chain (32) adjustable within angle (β). 5. The device for sorting boards according to claim 1, characterized in that the pushing cylinders (11, 12, 12.1, 12.2) are equipped with suitable independent drives. 6. The device for sorting boards according to claim 1, characterized in that the endless conveyor chains (37, 38, 39) within the input conveyor (4), and the endless conveyor chains (40, 41, 42) within the sorting conveyor (5 ), and the endless conveyor chains (45, 46, 47) within the sorting conveyor (5.1), and the endless conveyor chains (48, 49, 50) within the sorting conveyor (5.2) are parallel to each other, are in the same plane and are located in an identical position. 7. A device for sorting boards according to claim 1, characterized in that the pushing cylinder (11) together with the endless conveyor chain (40), the pushing cylinder (12.1) together with the endless conveyor chain (45) and the pushing cylinder (12.2) together with the endless conveyor chain (48) is preferably arranged to move in the transverse direction. 8. The device for sorting boards according to claim 1, characterized in that it consists of a selectable number of parallel sorting lines (3), (3.1) - (3.n), which are interconnected based on a through flow, with a defined optionally by the number of transverse conveyors (15), (16), (16.1), (16.2), (16.3) - (16.n) the design determined by choice. 9. The device for sorting boards according to claim 8, characterized in that each individual sorting line (3), (3.1), (3.n) consists of a selectable number of sequentially arranged sorting conveyors (5), (5.1), (5.2), (5.n). 10. A device for sorting boards according to claim 1, characterized in that at least one braking conveyor (2) is located in front of the sorting line (3), and at least one braking conveyor (17) is located in front of the sorting line (3.1), whose longitudinal axis is preferably offset by an angle (α) from the perpendicular to the longitudinal axis of the sorting line (3) and the sorting line (3.1), respectively. 11. The device for sorting boards according to claim 10, characterized in that the braking conveyors (2) and (17) are equipped with an adjustable shutter (36), which is attached to them with the ability to move over the transportation zone. 12. A method for sorting pre-processed approximately equally long boards sawn to a certain length, which arrive at the sorting line at a high speed, characterized in that the endless conveyor chains (40, 45, 48) arranged transversely, are located within the respective sorting conveyors (5), respectively (5.1), respectively (5.2), in the node of a separate sorting line (3), (3.1) - (3.n) and following each other in a linear sequence, as rules are adjusted before sorting in such a way that the infinite conveyor chains (40, 45, 48) arranged to move are equally spaced from adjacent, respectively parallel, fixed endless conveyor chains (41, 42), respectively (46, 47), respectively (49 , 50), as a result of which this distance corresponds to the lengths of the sorted boards (14), while the pushing lever (6) on the inlet conveyor (4), designed for automatic sorting of the boards (14) and adjusted to sort the boards (14) into After a certain quantitative sequence, for example, even - odd, or some other one, pushes out quantitatively sorted boards (14) onto line (8) as automatically sorted boards (14.1) that move on an infinite flow chain (13) and as a result fall freely on the popped side into the transverse conveyor (15), which is lower, into which they from their opposite end are ultimately also pushed by the pushing cylinder (11), and the sorting conveyors (5, 5.1, 5.2) are designed for manual sorting boards (14) in such a way that boards (14) that were not sorted as boards (14.1) come from the inlet conveyor (4) via line (7) and through an endless flow chain (13) and pushing cylinder (11) to the first sorting conveyor (5), where they are subjected to manual sorting carried out by one or more workers (10) in such a way that they push or pull the near end of the boards (14) that do not meet the criteria and requests determined in advance, respectively, by line (7) along which they move past an infinite flow line th circuit (13.1), and then they are manually sorted boards (14.2) fall on the cross conveyor (16), located below, to which they are expelled from their opposite end and push the cylinder (12). 13. The method according to p. 12, characterized in that on the sorting conveyor (5.1) the worker (10), who wants to manually sort the board (14) out of circulation on the sorting line (3), pushes or pulls this board to the line (9) As a result, its end passes through an endless flow chain (13.2) and it falls like a manually sorted board (14.2) onto the transverse conveyor (16.1), which is lower, onto which it is pushed by the pushing cylinder (12.1). 14. The method according to p. 12, characterized in that on the sorting conveyor (5.2) the worker (10), who wants to manually sort the board (14) out of circulation on the sorting line (3), pushes or pulls it to the line (9), as a result, its end passes through an endless flow chain (13.3) and it falls like a manually sorted board (14.2) onto a transverse conveyor (16.3) below, onto which it is pushed by a pushing cylinder (12.2) at the opposite end. 15. The method according to claim 12, characterized in that after leaving the sorting conveyor (5.2), the leveling lever (43) aligns the ends of the boards (14) which are not sorted, and then the boards (14) move on the output conveyor (22) to a storage area intended for this purpose, for example on a pallet, etc. 16. The method according to p. 12, characterized in that the boards (14.1), automatically sorted on the basis of the quantitative principle, move on the transverse conveyor (15), and preferably by means of a braking conveyor (17), to the inlet conveyor (4) of the adjacent sorting line (3.1) on which automatic sorting of boards (14.1) is carried out by means of a pushing lever (20), and workers (10) perform manual sorting of boards (14.2), as described above in connection with the sorting line (3). 17. The method according to p. 12, characterized in that the automatically sorted boards (14.1), as a rule, move further to one of the adjacent sorting lines (3.1) and (3.n), respectively, while the manually sorted boards (14.2) move to the storage area designated for this purpose.

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