• 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:
    The present invention relates to methods for producing construction elements which outermost surface is coated with coating elements (106) such as natural stones or the like. For forming the outermost surface, the method comprises mounting an arrangement (105) comprising the coating elements (106) layered on reinforcement means (107) and an elastic member (108) arranged on the layered coating elements and protruded into slits between the coating elements on a concrete layer (101) and removing the elastic member. The invention relates also to the arrangement (105) for producing the construction elements according to the method, and a lifting means (110) for use in the method.
    公开号:FI20195594A1
    申请号:FI20195594
    申请日:2019-07-01
    公开日:2020-07-15
    发明作者:Teppo Vuohelainen
    申请人:Stonelement Oy;
    IPC主号:
    专利说明:

    METHOD FOR PRODUCING CONSTRUCTION ELEMENT
    FIELD The present invention relates to methods for producing construction elements, in particular to methods for producing construction elements comprising an outermost surface coated with natural stones or the like. The invention relates also to lifting means for use in the method and to arrangements for producing the outermost surface of the construction element.
    BACKGROUND Constructing a stone wall on location is costly, time consuming and leaves the site cluttered with piles of stone and other masonry construction materials and debris. It is also subject to weather conditions, which are unpredictable. In order to avoid the above-mentioned problems, numerous methods for preparing prefabricated construction elements have been developed. For example, US 5624615 and US 9,975272 disclose methods for producing reinforced construction elements, wherein natural stones are loaded on a bottom of a mould.
    Slits between the natural stones are filled with sand prior to installing reinforcing structures and to pouring concrete to the mould. FI 124044 discloses an alternative method for producing construction elements comprising mounting an arrangement comprising stone-based coating material pre-assembled on reinforcement means onto uncured self-compacting concrete.
    One challenge of the methods cited above is how to avoid leaking of wet concrete = on the outermost surface of the construction element. This is a particular challenge . when self-compacting concrete is used. Furthermore, the methods are suitable for 25 producing construction elements wherein only one of their outermost surfaces is 7 coated with natural stones. For making a two-sided stone wall by using construction E elements produced by the methods described above, two construction elements has 3 to be placed back to back. > S Thus, there is still need for further methods for producing construction elements.
    SUMMARY The following presents a simplified summary in order to provide a basic understanding of some aspects of various embodiments of the invention. The summary is not an extensive overview of the invention. It is neither intended to identify key nor critical elements of the invention, nor to delineate the scope of the invention. The following summary merely presents some concepts of the invention in a simplified form as a prelude to a more detailed description of exemplifying embodiments of the invention. In accordance with the invention, there is provided a new method for producing a construction element, the method comprising steps of a) providing a mould, b) optionally pouring to the mould an admixture comprising basic concrete, c) pouring to the mould an admixture comprising self-compacting concrete to produce a concrete layer and d) for forming a first outermost surface of the construction element o providing an arrangement comprising e coating elements such as stones layered on reinforcement means, e an elastic member arranged on the layered coating elements and protruded into slits between the coating elements, o mounting the arrangement on the concrete layer, and o removing the elastic member, o In accordance with the invention, there is provided also a new arrangement N comprising
    K 25 o coating elements such as stones layered on reinforcement means and > o an elastic member arranged on the layered first coating elements and i protruded into slits between the coating elements. 3 In accordance with the invention, there is provided also a new lifting means for use 2 in the method according to claim 1. - 30 A number of exemplifying and non-limiting embodiments of the invention are described in accompanied dependent claims.
    Various exemplifying and non-limiting embodiments of the invention and to methods of operation, together with additional objects and advantages thereof, are best understood from the following description of specific exemplifying embodiments when read in connection with the accompanying figures. The verbs “to comprise” and “to include” are used in this document as open limitations that neither exclude nor require the existence of also unrecited features. The features recited in depending claims are mutually freely combinable unless otherwise explicitly stated. Furthermore, it is to be understood that the use of "a" or "an", i.e. a singular form, throughout this document does not exclude a plurality.
    BRIEF DESCRIPTION OF FIGURES The exemplifying and non-limiting embodiments of the invention and their advantages are explained in greater detail below with reference to the accompanying figures, in which figure 1A shows the first stage of a non-limiting exemplary embodiment of a method of the present invention wherein two concrete sublayers have been poured to a mould, figure 1B shows a non-limiting exemplary embodiment of the invention wherein the construction element includes two concrete sublayers separated by a heat isolating means, figure 2 shows the second stage of a non-limiting exemplary embodiment of a o method of the present invention wherein an arrangement including a first outermost > surface of the construction element is produced, S figure 3 shows the third stage of a non-limiting exemplary embodiment of a method O of the present invention wherein the arrangement of figure 2 is mounted on the E 25 concrete layer of figure 1A in the aid of a lifting means. > 2 figure 4 shows the fourth stage of a non-limiting exemplary embodiment of a method = of the present invention wherein the lifting means is removed, and the first outermost N surface of the construction element is produced,
    figure 5 shows an exemplary method for cleaning the construction element of the present invention, figure 6 shows the first stage of a non-limiting exemplary embodiment of a method of the present invention wherein the construction element is produced on a curved mould, figure 7 shows an exemplary stage of a non-limiting embodiment of a method of the present invention wherein a curved arrangement comprising the first outermost surface of the construction element is mounted on a curved concrete layer, figure 8 shows another exemplary stage of a non-limiting embodiment of a method of the present invention wherein a curved arrangement comprising the first outermost surface of the construction element has been mounted on a curved concrete layer, figure 9 shows an exemplary lifting means suitable for use in the method of the present invention, and — figure 10 demonstrate exemplary non-limiting engaging means of the lifting means.
    DESCRIPTION The specific examples provided in the description given below should not be con- strued as limiting the scope and/or the applicability of the appended claims. Lists and groups of examples provided in the description given below are not exhaustive = 20 unless otherwise explicitly stated.
    N N According to one embodiment the present invention relates to a method for = producing a construction element which outermost surfaces comprise coating I elements such as stones. The method comprises the following steps a 3 a) providing a mould, LO 25 b) optionally pouring to the mould an admixture comprising basic concrete, > c) pouring to the mould an admixture comprising self-compacting concrete to produce a concrete layer and d) for forming a first outermost surface of the construction element o providing an arrangement comprising e coating elements such as stones layered on reinforcement means, e an elastic member arranged on the layered coating elements 5 and protruded into slits between the coating elements, o mounting the arrangement on the concrete layer, and o removing the elastic member.
    For illustrative purposes the method has been divided in different stages shown in the figures.
    The first stage of the method comprising steps a) - c) is shown in figure 1A and 1B as non-limiting exemplary embodiments.
    Accordingly, an admixture comprising self- compacting concrete is poured to the mould 100 to produce a concrete layer 101. The admixture may consist of self-compacting concrete, or it can comprise a mixture of self-compacting concrete and one or more basic concretes.
    Self-compacting concrete is liquid, cohesive concrete with the ability to condense without gravity and without traditional concrete vibration (The European Guidelines for Self-Compacting Concrete.
    Specification, Production and Use; http://www efnarc.org/pdf/SCCGuidelinesMay2005.pdf). A particular — self- compacting concrete comprises aluminate cement.
    The self-compacting concrete forms also a surface suitable for forming the first outermost surface of the construction element.
    The concrete layer may comprise two or more concrete sublayers, but the o uppermost sublayer in the mould comprises self-compacting concrete. a According to a particular embodiment the method comprises pouring to the mould 25 — prior to step c) an admixture comprising basic concrete.
    A basic concrete comprises > general purpose cement, such as general-purpose Portland cement or general- E purpose blended cement.
    General-purpose blended cements contain typically 3 Portland cement and more than 5% of either fly ash, ground slag, amorphous silica 3 or a combination of these.
    Other components of the basic concrete are water and aggregates such as sand and crushed rocks.
    According to this embodiment for producing the concrete layer 101 the method comprises
    = pouring to the mould an admixture comprising basic concrete to produce a first concrete sublayer 101a, and = pouring onto the first concrete sublayer an admixture comprising self- compacting concrete.
    Thus, the concrete layer 101 consists of two concrete sublayers 101a and 101b comprising basic concrete and self-compacting concrete, respectively. The use of a layer of basic concrete below a layer of self-compacting concrete is preferable when the second outermost surface of the construction element is not modified. According to a particular embodiment recycled material is admixed the concrete of step b) and/or c). Exemplary recycled material include crushed rubber, crushed plastics, crushed burned clinker, crushed asphalt, crushed concrete and crushed bricks. Also, various crushed polymers, preferably crushed recycled polymers can be admixed to the concrete.
    According to another embodiment, the concrete layer 102 comprises two concrete — sublayers 102a, 102b, and a heat insulating means 103 therebetween. The concrete layers are engaged to each other with plurality of shafts, one of which is presented in figure 1B with reference number 104. According to this embodiment the method comprises for producing the concrete layer 102 " pouring to the mould a first admixture comprising concrete to produce a first concrete sublayer 102a, and = arranging a heat insulating means 103 on the first concrete sublayer, = pouring an admixture comprising self-compacting concrete on the heat = insulating means, and preferably "= engaging the first concrete sublayer to the second concrete sublayer. = 25 The first concrete layer and the second concrete layer can be made of same or I different type of concrete. At least the second concrete sublayer 102b comprises < self-compacting concrete. LO The first outermost surface of the construction element comprises coating elements > such as stones, preferably natural stones. Accordingly, slits between the coating elements cannot be avoided.
    Figure 2 shows an arrangement 105 comprising coating elements 106 such as stones layered on reinforcement means 107 and an elastic member 108 arranged on the layered coating elements and protruded to slits between the coating elements. In order to protrude to the slits between the coating elements, the elastic member is pressed between the layered coating elements and a non-elastic member 109. The arrangement is preferably provided in the aid of a lifting means 110 comprising the non-elastic member and plurality of rods adapted to be engaged to the reinforcement means. One of the rods is marked in figure 2 with reference number
    111. The rods can be engaged to the reinforcement means mechanically or magnetically. When magnetism is used, the lifting means includes preferably an electromagnet, and the rods and the reinforcement means are made of ferromagnetic material such as steel or iron. According to another embodiment, the magnet is a permanent magnet such as neodymium magnet. According to an exemplary embodiment the providing of the arrangement 105 comprises the following steps: o layering the coating elements 106, such as stones to a reinforcement means 107, o arranging an elastic member 108 on the layered coating elements, o providing a lifting means 110 comprising plurality of rods 111, o engaging plurality of rods 111 to the reinforcement means, and o pressing the elastic member between the layered coating elements and a non- o elastic member 109 by pulling the plurality of rods towards the non-elastic S member i.e. in y-direction of the coordinate system 299 so that the elastic 5 25 member protrudes to the slits between the coating elements. > The pulling direction is shown in figure 2 also with an arrow. E According to a preferable embodiment the lifting means comprises an 3 electromagnet and the plurality of rods and the reinforcement means are made of 3 ferromagnetic material such as iron or steel. Accordingly, the engaging and N 30 releasing the plurality of rods from the reinforcement means is performed by switching on and off the electromagnet, respectively.
    The coating elements are preferably stones, more preferably natural stones.
    Exemplary natural stones are marble, granite, diabase, feldspar, flintstone and basalt.
    A preferable natural stone is slate.
    Also, artificial stones made from recycled materials such as recycled glass, crushed bricks and crushed concrete can be used as coating elements.
    The reinforcement means is preferably made of ferromagnetic material such as iron or steel.
    An exemplary reinforcement means is a typical reinforcement mesh.
    Another exemplary reinforcement means is a fiber, preferably steel fiber or plastic fiber.
    The elastic member may be made of any elastic material such as foam plastic, silicone and Styrofoam.
    A particular elastic material is foam plastic.
    The non-elastic member may be made of any material which is less elastic than the elastic material.
    Preferable non-elastic materials are steel, aluminum and iron.
    Further exemplary non-elastic members are plates made of plastic and plywood.
    According to a particular embodiment the non-elastic member is part of the lifting means.
    According to another particular embodiment also the elastic member is part of the lifting means.
    The next stage, shown in figure 3, comprises mounting the arrangement 105 on the concrete layer 101 using the lifting means 110. The mounting is performed before the concrete has cured.
    The arrangement is submerged to predetermined depth d to the concrete layer by moving the lifting means in (-)-y-direction of the coordinate system 399. Since the elastic member fills any slits between the layered coating = elements, the uncured concrete does not leak to the first outermost surface of the construction element. = 25 The next stage, shown in figure 4, comprises moving the lifting means 110 in y- I direction of the coordinate system 499, releasing the rods 111 from the 3 reinforcement means, and removing the elastic member from the first outermost D surface.
    Final steps of the method include extruding the construction element from = the mould and cleaning the construction element e.g. by brushing and/or washing.
    An exemplary finishing by washing is shown in figure 5.
    The method of the present invention is applicable also for producing construction elements wherein the second outermost surface is modified. Modification of the second outermost surface, i.e. the surface which is towards the bottom of the mould can be done by one of more methods known in the art.
    According to one embodiment, the concrete is poured into a mould comprising 3D patterns. When the concrete has cured and the construction element has been removed from the mould, the 3D patterns of the mould are reproduced to the second outermost surface of the construction element.
    According to another embodiment a membrane, such as a raster fabric comprising the desired pattern or image and a surface retarder is placed in the mould followed by pouring of the admixture comprising self-compacting concrete. The surface retarder is a material adapted to retard hydradation reaction of the concrete.
    According to one embodiment an area of the membrane comprising the pattern or image comprises the surface retarder. According to another embodiment the area of the membrane not comprising the pattern or image comprises the surface retarder. After the concrete has cured and the construction element is removed from the mould, the membrane is washed away, revealing a pattern or image that results from the contrast between the smooth cement surface and the exposed aggregate surface as depressions or humps in the second outermost surface of the construction element. Color pigments or aggregates of different colors can also be used in the concrete to further enhance a pattern or design.
    According to still another embodiment stones, recycled materials such as crushed > glass or pigments such as iron oxide is layered to the mould prior to step a). After N the concrete is cured and the construction element has been removed from the = 25 mould, the material layered on the bottom of the mould is exposed. 7 The final steps of the method comprise typically removing the construction element E from the mould, transferring to vertical arrangement and washing the outermost 3 surfaces with water. The washing shown in figure 5 removes any filler materials or 3 membranes or the like from the outermost surfaces. The washing can be done e.g. N 30 by using high pressure cleaners.
    The mould does not need to be straight as in the embodiments disclosed above, but also non-straight moulds such as curved, concave and convex moulds can be used.
    When a non-straight mould is used in the method, all materials e.g. the coating elements, non-elastic members, elastic members, admixtures comprising self- compacting concrete and the reinforcement means disclosed above can be applied.
    The use of non-straight mould in the method has been demonstrated by exemplary non-limiting embodiments shown in figures 6-8. Figure 6 shows an embodiment wherein an admixture comprising self-compacting concrete 601 has been poured into a curved mould 600. According to this embodiment, the mould has been covered by a curved lid 612, and the admixture has been poured to the mould through ends of the mould.
    The pouring direction is shown in figure 6 with arrows.
    After the lid 612 has been removed, the first outermost surface is mounted on the concrete layer.
    Figure 7 shows an exemplary curved arrangement 705 comprising coating elements 706 such as stones layered on reinforcement means 707 and an elastic member 708 is arranged on the layered first coating elements and protruded to the slits between the coating elements.
    The elastic member has been pressed between the layered coating elements and a non-elastic member 709. The figure shows also the mounting of the arrangement 705 on the curved concrete layer 701 using the lifting means 710. The mounting is performed before the concrete has cured.
    The arrangement is submerged to predetermined depth to the concrete layer by moving the lifting means in (-)-y-direction of the coordinate arrangement 799. Since the elastic member fills any slits between the layered coating elements, the uncured = concrete does not leak to the first outermost surface of the construction element. . Figure 8 shows another curved arrangement 805 comprising the coating elements 25 806 such as stones layered on reinforcement means 80/ and an elastic member 7 808 arranged on the layered coating elements and protruded to the slits between E the coating elements.
    The elastic member has been pressed between the layered 3 coating elements and a non-elastic member 809, and the arrangement has been 3 mounted on a curved concrete layer 801. © 30 According to another embodiment the present invention concerns an arrangement 105 comprising o coating elements 101 such as stones layered on a reinforcement means, and o an elastic member 108 arranged on the layered coating elements and protruded into slits between the coating elements. The coating elements of the arrangement are preferably stones, more preferably natural stones. Exemplary natural stones are marble, granite, diabase, feldspar, flintstone and basalt. A preferable natural stone is slate. Also, artificial stones made from recycled materials such as recycled glass, crushed bricks and crushed concrete can be used as coating elements. The reinforcement means of the arrangement is preferably made of ferromagnetic material such as iron or steel. An exemplary reinforcement means is a typical reinforcement mesh. Another exemplary reinforcement means is a fiber, preferably steel fiber or plastic fiber. The elastic member of the arrangement may be made of any elastic material such as foam plastic, silicone and Styrofoam. A particular elastic material is foam plastic. The arrangement can be straight such as 105, or non-straight such as 705 or 805. The use of an arrangement in the method has advantages. The elastic member of the arrangement prevents the self-compacting concrete from leaking to the outermost surface of the construction element during assembly. Furthermore, it prevents the coating elements from moving on the reinstatement means during transportation, mounting, vibrating and the like. This is important in particular when producing non-straight, such as curved, concave and convex construction elements. O Still another advantage of the use of the arrangements is that they do not need to N be assembled in the same site as the entire construction element. According to an S exemplary embodiment plurality of arrangements are prepared on a guarry, stacked O 25 on each other, bundled, and transported to the final production site, where the = bundles are removed, and the arrangements are used one by one in the method for 3 producing construction elements as described above.
    LO 3 According to still another embodiment the present invention concerns a lifting means
    O N suitable for use in the method. An exemplary lifting means is shown in figure 9, and its exemplary encaging means are shown in figure 10.
    The lifting means 910 comprises plurality of rods, two of them are marked with reference numbers 911a and 911b. The rods are adapted to be engaged to the reinforcement means as described above. The lifting means comprises typically also means adapted to move the rods in + y-direction of the coordinate system 999. The movement can be performed e.g. by threads 913a or by means 913b adapted to operate with pressurized gas or hydraulics. According to a preferable embodiment the rods 1011a and the reinforcement means 1007 is made of ferromagnetic material such as steel or metal, and the lifting means comprises an electromagnet. The electromagnet is not shown in the figure. Thus, the engaging and releasing is performed by switching on and off the electromagnet. An exemplary enganging means of this type is shown in figure 10A. Another exemplary magnet is a neodymium magnet. According to another embodiment the rods 1011b, 1011c are engaged to the reinforcement means 1007 mechanically. An exemplary mechanical engaging means is shown in figure 10B. According to a preferable embodiment the lifting means comprises means for adjusting how deeply the arrangement is submerged to the concrete layer. The means is exemplified in figure 10 by the numbered markings in the rod 1011a. The finished construction elements can used not only as vertical structures as walls, pillars and fences but also in various horizontal structures such as stairs, walkways and driveways. o The specific examples provided in the description given above should not be S construed as limiting the scope and/or the applicability of the appended claims.
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    权利要求:
    Claims (14)
    [1] 1. A method for producing a construction element, the method comprising steps of a) providing a mould (100, 700, 800), b) optionally pouring to the mould an admixture comprising basic concrete, c) pouring to the mould an admixture comprising self-compacting concrete to produce a concrete layer (101, 102, 701, 801) and d) for forming a first outermost surface of the construction element o providing an arrangement (105, 705, 805) comprising e coating elements (106, 706, 806) such as stones layered on reinforcement means (107, 707, 807), e an elastic member (108, 708, 808) arranged on the layered coating elements and protruded into slits between the coating elements, o mounting the arrangement on the concrete layer, and o removing the elastic member.
    [2] 2. The method according to claim 1, wherein the admixture of step b) comprises general purpose cement such as Portland cement, water and aggregates.
    [3] 3. The method according to claim 1 or 2 wherein the providing of step d) comprises o layering the coating elements (106, 706, 806), such as stones on the reinforcement means (107, 707, 807), o o arranging the elastic member (108, 708, 808) on the coating elements, N o providing a lifting means (110, 710, 910) comprising a non-elastic 5 25 member (109, 709, 809, 909) and plurality of rods (111, 711, 911a, o 911b), E o engaging the plurality of rods to the reinforcement means, and 3 o pressing the elastic member between the layered coating elements LO and the non-elastic member by pulling the plurality of rods towards a o 30 non-elastic member in y-direction of the coordinate system (299, 799,999) so that the elastic member protrudes the slits between the coating elements.
    [4] 4. The method according to claim 3 wherein lifting means comprises an electromagnet, the plurality of rods are made of ferromagnetic material and the reinforcement means are made of ferromagnetic material, and wherein the engaging comprises turning on the electromagnet.
    [5] 5. The method according to any of claims 1-4 wherein the mounting comprises submerging the arrangement to a predetermined depth d in the concrete layer.
    [6] 6. The method according to any of claims 1-5 wherein the elastic member comprises foam plastic, Styrofoam or silicone, preferably foam plastic.
    [7] 7. The method according to any of claims 1-6 wherein the coating elements are selected from natural stones preferably selected from marble, granite, diabase, feldspar, flintstone and basalt, or artificial stones made from recycled materials such as recycled glass, recycled crushed concrete, recycled crushed bricks.
    [8] 8. The method according to any of claims 1-7 wherein the admixture of step b) and/or the admixture of step c) comprises one or more recycled materials preferably selected from crushed rubber, crushed plastics, crushed burned clinker, crushed asphalt, crushed bricks, crushed recycled concrete, and crushed recycled polymer.
    [9] 9. The method according to any of claims 1-8 wherein the mould comprises 3D- patterns.
    [10] 10. The method according to any of claims 1-8, comprising layering to the mould, prior to step c) and the optional step b) one or more of stones and/or recycled = material preferably selected from crushed rubber, crushed plastics, crushed . 25 burned clinker, crushed asphalt, and crushed bricks, crushed recycled polymer. 7
    [11] 11. The method according to any of claims 1-8 comprising layering to the mould, E prior to step c) and the optional step b) a membrane comprising a pattern or 3 image and a surface retarder. 3 30
    [12] 12. The method according to any of claims 1-11 comprising removing the i construction element from the mould, and preferably cleaning the construction element.
    [13] 13. An arrangement (115, 705, 805) comprising o coating elements (106, 706, 806) such as stones layered on reinforcement means (107, 707, 807) and o an elastic member (108, 708, 808) arranged on the layered coating elements and protruded into slits between the coating elements.
    [14] 14. A lifting means (910) for use in the method according to any of claims 1-12, the lifting means comprising o an electromagnet, o plurality of rods (911a, 911b) made of ferromagnetic material, and adapted to be engaged to reinforcement means (907) made of ferromagnetic material o anon-elastic member (909) and o means (913a, 913b) adapted to move the plurality of rods in (+) y- direction of the coordinate system (999). oO
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    同族专利:
    公开号 | 公开日
    FI128528B|2020-07-15|
    WO2021001598A1|2021-01-07|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US3839519A|1971-01-11|1974-10-01|G Weiner|Method of making building panel|
    NO129989B|1972-07-10|1974-06-24|Grubstad Alfred|
    DE2604227A1|1976-02-04|1977-08-11|Bernd Peters|Large paving slats for patterned paving - has surface comprising tile groups on concrete type base|
    SE8800445L|1988-02-10|1989-08-11|Christer Franzen|Mould casting walls with unworked - has inside surfaces provided with lining of foam rubber|
    US5236975A|1989-06-01|1993-08-17|Kabushiki Kaisha Zokei|Concrete non-cure coating material, as well as concrete products or concrete structural products with surface pattern or decoration using said material and production process therefore|
    US5624615A|1995-08-29|1997-04-29|Sandorff; Daniel R.|Method of manufacturing modular stone panels|
    US9975272B1|2009-04-28|2018-05-22|Natural Stone Wall Solutions|Stone wall construction method|
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    PCT/FI2020/050450| WO2021001598A1|2019-07-01|2020-06-24|Method for producing construction element, an arrangement and a lifting means for use in the method|
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