• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    This invention relates to the woodworking industry. The purpose of the invention is to increase the strength properties of extruded products. The initial mixture is fed to a press chamber (PC), where it is forcibly compacted, and then subjected to extrusion (ish). At the same time, the longer particles are oriented parallel to the Ilin direction, and the outer layers of the mixture in the PC are pre-compacted, and they are 1.5-2 times compacted. After filling the PC, the upper 23 is moved to the position between the upper –– bridges 14. In this position, the punches 17, 23 pre-seal the coating layers 1.5–2.5 times. As a result, small particles that are already in the longitudinal direction are fixed in their position, which is preserved by the subsequent NSH. Punch 23 enters a certain area in space. between the upper bridges 14 and during the reciprocating movement of the slats 25, the mixture introduced into the PC is modified. Immediately after filling with the PC 9 mixture, the carriage 25 is brought into position in which the upper punch 23 is located congruently above the lower punch 17. Then, the mixture has the / TschTs of POM-1 piston -12. 2 sec. and 2 z. p. fats, 10 ill. ze 26 S ffi O) C 00 00 4 G
    公开号:SU1384190A3
    申请号:SU843825253
    申请日:1984-12-20
    公开日:1988-03-23
    发明作者:Хеггеншталлер Антон
    申请人:Anton Kheggenshtaller;
    IPC主号:
    专利说明:


    s
    Figm
    eleven
    The invention relates to the woodworking industry, namely to the manufacture of extruded products from small elongated wood particles.
    The purpose of the invention is to increase the strength properties of extruded products.
    Figure 1 presents the extruded product obtained by the proposed method, a general view; Fig, 2 - the same, made with channels; Fig, 3 a section aa on Fig, 2; Fig. 4 shows a device for carrying out the method, a longitudinal section; Fig. 5 shows a press chamber of a device for carrying out the method, a cross section (. shown in the direction, vertical directions of extrusion); in fig. 6 - the same, with pre-compaction punches at the time of extrusion; Fig, 7 - boot device (partially) with a scraper; on Fig - extruded product obtained by the proposed method, made with channels, cross section; Fig, 9 - piston, axonometric; Fig, 10 - the same, option.
    The method is carried out as follows.
    The initial mixture is fed to a press chamber, where it is pre-compacted, and then subjected to extrusion. In this case, longer particles are oriented parallel to the direction of extrusion, and the outer layers in the press-chamber of the mixture are compacted to the preliminary one: they condense them by 1.5-2 times.
    Example 1 A channel-containing plate with a thickness of 80 mm and a width of 300 mm was made from small wood particles. The diameter of the channels is 40 mm, and the channels are located at a distance of 20 mm. The 50% by weight of the air-resistant binder, fine wood particles, consist of pinwood coniferous shavings, the shaving length being 15–30 mm, and their thickness is 0–1.2 mm. a press chamber, in which, by means of jumpers, the pinch chips are generally aligned parallel to the extrusion axis.
    The flexural strength of the slab thus obtained is 5.3 N / mm.







    o
    0
    five
    0
    Example 2 Example 1 is repeated, with the difference that plates for covering a field 35 mm thick, containing 15 wt.% Chips: 1-shaving chips 15-30 mm long and 0.5-1.2 mm thick, are made. Here, the pre-compaction of the outer layers is 1: 1.5,
    The plate has a bending strength of 2.8 P / mm
    Example, 3, Example 1 is repeated, with the difference that the baffles 5 with a thickness of 120 mm, containing 65 May, are made of% 15–30 mm long and 0.5–1.2 mm thick, are manufactured with channels. The pre-compaction of the outer surfaces is 1: 2.5,
    Partitions have a bending strength of 5.8 N / mm2.,
    Example 4 (for comparison) Example 2 is repeated with the difference that the longer chips, t, e. the shavings are not oriented and the pre-compaction is 1: 1.4,
    The plates have a flexural strength of 1.2 N / mm,
    A comparison of the results of examples 2 and 4 suggests that in the absence of orientation of longer shavings and failure to comply with the proposed lower precompaction limit, the flexural strength significantly decreases and practically corresponds to the flexural strength of a plate containing no studs. N / mm,
    Example 5 (for comparison), Example 3 is repeated with the difference that the pre-compaction is 1: 2.6.
    .0
    bend 5.7 N / mm,
    Comparison of the results of examples 3 and 5 indicates that when the upper precompaction limit is exceeded, the positive effect is not further enhanced, but on the contrary, is somewhat worse.
    The proposed device is intended for the manufacture of pressed products .1 with the upper 2 and lower 3 coating layers and the middle layer 4, the upper 2 and lower 3 coating layers must be pre-compacted compared to the middle layer. At least in layers x 2 and 3, in particular, longer small parts
    0
    five
    0
    five
    The pillars are located in the direction 6 parallel to or almost parallel to the axis 5 of the extrusion. The article can be made with passing in the longitudinal direction. channels 7. The layer 8 forming the channel wall is made with a higher degree of compaction than the average one 4.
    The device comprises a press chamber 9 for a press mass 10, made in accordance with the contour 11 of a conventional piston 12, It has a preferably rectangular cross section that is made according to the pressed product 1. This piston 12 is guided between the walls 13 of the press chamber vertically to the plane according to FIG. 5. In the area of the upper and lower sides of the contour 11, a plurality of bridges 14 which are spaced apart from each other at a certain distance, for example, 8 mm, which are relatively thin walls and fixed on reb1eo. For wear parts it is recommended to use tape steel that is suitable for making a saw blade. Between the upper bridges 14 there is a free space for the mixture located in the loading device 15, which should freely fall into the press chamber 9. The space 16 between the lower bridges 14 includes toothed projections of the lower punch 17 of the pre-compaction that is reciprocating movements in the vertical direction 18. The free end surfaces of these protrusions form strip-like pressing surfaces 19. Lintels 14 are inserted with a clearance in accordance with the hole of the lower punch 4.
    The loading device 15 is made with the possibility of reciprocating movement.
    The bridges 14 have the function of orientation of the fine particles of the mixture in the loading device during the free fall, so that the chips are mainly informed by the parallel orientation relative to the pressing axis 2 (this orientation 6 of chips is positively influenced by the loading device 15 with its outlet 21 reciprocates along jumpers 14). The lower edge of the loading device .13 may be located at a distance from the upper edge of the upper bridges 14. In this case, a small amount of the mixture may settle on the upper edge of the bridges 14 and form a bridge. In order for the accumulated particles to be reliably fed evenly into the press chamber 9, at least one scraper 22 is provided on the moving loading device 15, which, due to its 5 movement, also contributes to the orientation of the small particles along the extrusion axis 5.
    The device also comprises an upper pre-compaction punch 23, a channel 24 in which the curing process is carried out. The loading device 15 is located on the carriage 25 carrying the upper punch 23. Mechanisms 5 are mounted on the carriage 25, bringing the upper punch 23 to the final position.
    During pressing, jumpers 27 are formed in the product. The face surface of the piston may have a protruding profile 28 and two intermediate pistons 29 which are slightly bent backward, passing into each other. Here, the edge portions between the descent lines 30, 31 are provided with wavy deflecting 32, as a result of which a more intensive connection of individual portions of the pressed product is achieved without significantly affecting the orientation of the chips.
    The end surface of the piston 12, which is recommended to be cooled, may have a concave implementation profile 33, which passes into the serrated profile 34 along the edges of the piston, which is strongly rounded. Fig. 10 shows the execution of the end surface of the piston 12 in the form of a concave profile 33, which passes into the serrated profile 34 along the edges of the piston, which is strongly rounded.
    The device works in a sweet way,
    After the press chamber 9 is filled, the upper punch 23, due to the longitudinal movement parallel to the axis 5 5, is moved to the position between them by jumpers 14. In this position, the punches 17, 23 pre-seal the initial mixture
    0
    five
    0
    five
    0
    15
    approximately in the vertical direction (with horizontal extrusion.). The protrusions of the punches 17, 23 pass through the spaces 16 between the bars 1A and reach their end position (Fig. 6), corresponding to the profile contour 11 (Fig. 5). In this way, pre-compaction of the cover layers Q 2, 3 is achieved, which, however, should be carried out only to such an extent that subsequent extrusion of the sheet ensures a reliable connection of the individual sections of the press with each other. It is advisable to pre-seal in the ratio of 1: 1.5 - 1: 2.5. The result of the pre-compaction is that the fine particles already in the longitudinal direction 20 are fixed in their position, which is maintained during subsequent extrusion pressing. The piston 1 is installed with the possibility of a horizontal reciprocating motion. Let the movements of the piston 12 be symbolically depicted by the upper and lower bridges 14, and the position of the lower punch 17 and its direction of displacement 18 are also indicated. The punch 23 enters a certain part into the space 16 between the upper bridges 14 and during the reciprocating movement of the carriage 25 has additional tools only in the covering layers x 2, 3, and in the middle layer the particles have a certain degree of deposition, it is recommended to return - the forward movement is performed only during the loading of the spaces 16 between the bridges 14, while the loading of the press chamber to form the middle layer 4 can be carried out with a very slow translational movement of the loading chamber special tools 15 In this case, the feed particles are not forcibly forced. The loading device 15 can be made, for example, so that it covers the entire Filling section of the bale chamber 9. In this case, the jumpers 14 oscillate along their length, which may have a small amplitude, but a greater frequency. - It is possible to achieve the longitudinal orientation of small particles parallel to the extrusion axis 5 without using the dynamic effect of the moving loader on the particle flow (Fig. 4). Such movement becomes possible due to the fact that the bridges 14 are connected on one end side with an oscillating device, for example a vibration magnet. The same is achieved by the fact that the jumpers remain fixed, while the loading device 15 makes a colo
    40
    45
    In addition, the protrusions of the punches 17, after filling with the mixture of the press chamber 9, the carriage 25 is brought to a position in which the upper punch 23 is located congruently above the lower Punch 17. Mechanisms 26 are mounted on carriage 25, leading the upper punch 23 to the final position (Fig. 5). Both of the punch 17, 23 remain in the final position (Fig. 5) when the subsequent extrusion is performed by means of the piston 12.
    The device achieves various results. If over the entire cross section of the extruded product 1 one wants to achieve mainly a longitudinal orientation of 6 chips, it is recommended to maintain a continuous reciprocating movement of the loading part, the distance of caipade 15 plays as long as. Catch 7 from each other. Dna lime press chamber 9 is not filled. However, pressed moldings distance if such a longitudinal orientation between the channels 7 is at the edge 23 does not lead to partial pre-compaction, although they have holes 20. The pressure of the anti-seals extends along the strip surface of the extrusion. On the surface of the finished product, pressing of the product receives only strip reverse reliefs, which, however, have no negative effect on the strength properties of the products. In case a coating, for example, plywood, is not applied to the pressed product, a slight grinding of the product surface is sufficient to remove these reliefs.
    In the case of the manufacture of extruded products 1 according to FIG. 2,
    Q 0 5 "
    shavings are present only in the coating layers 2, 3, and in the middle layer the particles have a certain degree of deposition, it is recommended to perform a reciprocating motion only during the loading of the space 16 between the bridges 14, while loading the press chamber to form the middle layer 4, it is possible to carry out with very slow translational movement of the loading device 15. In this case, the feeding fine particles are not forced to be oriented. The loading device 15 can be made, for example, so that it covers the entire Filling section of the bale chamber 9. In this case, the jumpers 14 oscillate along their length, which may have a small amplitude, but a greater frequency. - It is possible to achieve the longitudinal orientation of small particles parallel to the extrusion axis 5 without using the dynamic effect of the moving loader on the particle flow (Fig. 4). Such movement becomes possible due to the fact that the bridges 14 are connected on one end side with an oscillating device, for example a vibration magnet. The same is achieved by the fact that the jumpers remain fixed, while the loading device 15 makes a colo
    ani along the axis 5 extrusion, in addition, the protrusions of the punches 17,
    the divided role is played by the distance of channels 7 from each other. Dp of known extruded products, the distance between the channels 7 is at the edge 23 and does not lead to partial pre-compaction, although they have holes 20. The pressure of the anti-seals is distributed along the strip surface of the extrusion. On the surface of the finished, pressing the product receive only strip reverse reliefs, which, however, have no negative effect on the strength properties of the products. In case a coating, for example, plywood, is not applied to a pressed product, a slight grinding of the product surface is sufficient to remove these reliefs.
    In the case of the manufacture of extruded articles 1 according to FIG. 2,
    It is at least 1.5 times their radius. In contrast, it is proposed to reduce it. This distance corresponds to approximately half the diameter of the channel 7 (Fig. 8). The upper limit is not much less than the specified distance, but much less than the lower limit of the known distance. These dimensions ensure the optimal formation of a layer 8 adjacent to the individual channels 7 in the form of a vault. In addition, when carrying out the corresponding filling of the press chamber 9, the mid zone jumpers 27 located between the channels 7 have a significant number of fine particles oriented parallel to the extrusion axis 2. But,
    the closer the channels are located each
    to a friend, it is more difficult to fill the press chamber with small particles in free fall, which are under the cores 7 forming the rods. To avoid this drawback, the lower punch 17 together with the lower bridges 14 and also with their body make reciprocating translation across the axis 2 extrusion during the filling process, whereby the distribution of the mixture accumulated in the lower part of the bale chamber is achieved (Fig. 5).
     Pre-compacted mixture is extruded, preferably on a path of at least 200 mm, in particular 400-600 mm.
    The invention provides improved strength properties of extruded products.
    权利要求:
    Claims (4)
    [1]
    1. A method of manufacturing npeccoBaij products from small elongated wood particles by feeding the mixture into the press chamber of a preliminary flat compaction and subsequent extrusion pressing
    Q
    15
    20
    25
    . 35
    thirty
    40
    45
    908
    a piston press, characterized in that, in order to increase the strength properties of the pressed products, in the process of feeding the mixture into the press chamber, elongated wood particles are oriented parallel to the direction of extrusion pressing, and the outer layers are pre-compacted at a ratio of 1: 1.5 - 1: 2.5.
    [2]
    2. An apparatus for manufacturing extruded products from fine elongated wood particles, including a loading device associated with a press chamber equipped with an extrusion piston press and a flat pre-compact press located in the press chamber of the mixture across the extrusion press direction parallel to the direction of extrusion extrusion of the punches, as well as a heated channel for solidifying the mixture connected to the press chamber, characterized in that, in order to increase the strength Other properties of extruded products, the press chamber in the area of the loading device and in the area of the precompaction press is made with thin-walled bridges that are mounted on the edge parallel to the longitudinal axis of the extrusion press, and the pre-compaction press is made comb-shaped, with grooves for placing the bridges to the plane corresponding to the contour working surface of the press.
    [3]
     3. A device according to claim 2, characterized in that the loading device is provided with a scraper.
    [4]
    4. The device according to claim 2, characterized in that the working body of the piston press has a wavy surface of the side edges
     and the toothed surface of the working edge.
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    类似技术:
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    同族专利:
    公开号 | 公开日
    FI74233C|1988-01-11|
    AT58501T|1990-12-15|
    CA1249706A|1989-02-07|
    DK614284D0|1984-12-20|
    ES538507A0|1986-09-01|
    YU45015B|1991-06-30|
    EP0146752A1|1985-07-03|
    US4611979A|1986-09-16|
    DK614284A|1985-06-23|
    FI74233B|1987-09-30|
    JPS60157806A|1985-08-19|
    FI844613A0|1984-11-23|
    DK161684B|1991-08-05|
    NO163729B|1990-04-02|
    YU43393B|1989-06-30|
    DE3346469C2|1987-02-26|
    FI844613L|1985-06-23|
    NO163729C|1990-07-11|
    CS251091B2|1987-06-11|
    DK161684C|1992-01-27|
    YU207484A|1987-12-31|
    US4645631A|1987-02-24|
    DE3346469A1|1985-07-18|
    EP0146752B1|1990-11-22|
    DE3483644D1|1991-01-03|
    ES8608993A1|1986-09-01|
    DD232452A5|1986-01-29|
    YU103086A|1988-08-31|
    PT79695A|1985-01-01|
    NO844757L|1985-06-24|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    DE3346469A|DE3346469C2|1983-12-22|1983-12-22|
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