CN111576853A - Wood frame plate for concrete pouring - Google Patents

Abstract

The invention relates to the technical field of concrete pouring formworks in constructional engineering, in particular to a wood frame plate for concrete pouring. The utility model provides a wooden frame plate for concrete placement, includes wooden class rectangle plate, and this plate is including being used for with the front of concreting contact to and the fixed back that is provided with the pole, the pole distributes in the peripheral position on the plate back. The wood plate has lower material cost, and the back surface of the wood plate is provided with the bar frame, so that the strength of the plate is increased, and the surface-to-surface contact between adjacent bars can be utilized, thereby facilitating splicing and reducing the construction cost. The combination part is preferably arranged on one side of the bar, so that the flatness of plate splicing can be ensured, the front surfaces of the plates are basically positioned on the same plane, and assembling gaps and staggered joints are reduced.

Description

Wood frame plate for concrete pouring

Technical Field

The invention relates to the technical field of concrete pouring formworks in constructional engineering, in particular to a wood frame plate for concrete pouring.

Background

The common templates in the cast-in-place concrete structure in the prior building field comprise a steel aluminum template and a traditional wood template, and the two templates respectively have advantages and disadvantages.

The steel-aluminum template has the advantages that: 1. high strength, tight assembly, difficult deformation and rigid and straight external corner. 2. Because can make in advance at the template factory according to the drawing and accomplish, then transport to the scene and directly assemble, for traditional plank sheathing, to same building, its template dismouting construction efficiency height under the same condition of floor structure is high.

However, steel aluminum forms also have the following disadvantages, including: 1. due to the fact that the self weight is large, hoisting equipment is needed to hoist on a construction site, and the hoisting equipment is occupied for a long time. 2. The material cost of the steel-aluminum alloy is originally high, the steel-aluminum alloy is only suitable for buildings with the same design, the steel-aluminum alloy is customized, and if the steel-aluminum alloy is used for buildings with different designs, the waste rate exceeds 30%, so the cost is further increased. 3. Because the degree of difficulty of the cutting change of metal is great, therefore steel aluminium template in case the design, its leeway of revising is very little, and the flexibility is relatively poor to improper dismouting or fall the collision damage and lead to the unable use of monoblock template.

Traditional plank sheathing is at on-the-spot processing and build and assemble, its advantage: 1. the system can be corrected conveniently according to the field condition, and has strong flexibility and wide adaptability. 2. The cost of the material itself is low.

But the wooden form has the following obvious disadvantages: 1. the template has low strength, more supporting structures needing to be prevented from deforming, complex formwork supporting operation and low construction efficiency, and is difficult to meet the requirement of continuously shortening the construction period. 2. The manufacturing and building work of the on-site wood pattern is time-consuming and labor-consuming, and is continuously improved along with the increase of the construction labor cost.

Disclosure of Invention

The invention aims to provide a wood frame plate for concrete pouring, which integrates the respective partial advantages of the existing steel-aluminum template and the traditional wood template.

The wood template can be manufactured in a processing factory area on the premise of low material cost, and then is quickly and conveniently assembled on site, and has high strength.

The purpose of the invention is realized by the following technical scheme:

the wood frame plate for concrete pouring comprises a wood rectangular plate, wherein the plate comprises a front face and a back face, the front face is used for being in contact with poured concrete, the back face is fixedly provided with bars, and the bars are distributed on the periphery of the back face of the plate. The arrangement of the rods can improve the assembling performance while increasing the strength of the plate, so that the wooden plate is easy to assemble and cut.

Preferably, at least one side of the bar is flush with a side of the panel. The side surfaces of the bars are parallel and level with the corresponding side surfaces of the plates, so that the processing and the manufacturing are convenient, the butt joint and the assembly are convenient, and the materials are saved.

Preferably, the bar portion projects beyond the side edge of the plate or the corresponding side edge of the plate projects beyond the bar. The plate splicing seams are arranged on one side of the bar, and the splicing seam dislocation is further reduced.

Preferably, the side of the bar adjacent to the edge of the panel is provided with a joint or a matching part. The combination part and the matching part are convenient for splicing, positioning and fixing the plates, and can effectively resist the phenomenon that the splicing seam generated by uneven stress is misplaced during pouring and prevent the assembled plate from collapsing.

Preferably, the combining portion is provided with a slot, and the matching portion is provided with a projection, wherein the projection can be matched and positioned with the slot. The slot and the lug are matched and positioned, so that the structure is simple, the processing is convenient, and the slot and the lug are combined to be convenient to butt joint and disassemble.

Preferably, the socket includes a bottom, the projection includes a top, and the bottom and the top have a gap when the socket is engaged with the projection. Leaving the clearance can make the plate concatenation inseparabler, reduces the concatenation seam.

Preferably, the cross sections of the slot and the lug are trapezoidal or the cross sections of the slot and the lug are tooth-shaped. The plate plane alignment is convenient.

Preferably, the coupling portion includes a boss protruding at a side of the bar, and the fitting portion includes a recess to which the boss is fitted. When the convenient plate is used for assembling the wall cast-in-place formwork, the plate can be conveniently assembled and disassembled after the wall is solidified.

Preferably, longitudinal or transverse struts are fixed to the rear side of the plate within the region surrounded by the plate-surrounding bars. And the supporting strips are arranged in the standard plate or the wider plate, so that the supporting strength of the plate is increased, and the plate meets the force bearing requirement.

Preferably, the bar comprises a groove arranged opposite the bonding or mating portion. The arrangement of the groove is convenient for the clamping and positioning of the clamp.

The wood plate has lower material cost, and the bar frame is arranged on the back surface of the wood plate to ensure the strength of the wood plate, so that the strength of the wood plate is increased, and the surface-to-surface contact between adjacent bars can be utilized, thereby facilitating splicing and reducing the construction cost. The combination part is preferably arranged on one side of the bar, so that the flatness of plate splicing can be ensured, the front surfaces of the plates are basically positioned on the same plane, and assembling gaps and staggered joints are reduced.

Drawings

FIG. 1 is a schematic view of a panel B provided with stays;

FIG. 2 is a perspective view of a plate B provided with stays;

FIG. 3 is a sectional view taken along line A-A of FIG. 1;

FIG. 4 is a schematic structural view of a plate A;

FIG. 5 is a perspective view of a plate A;

fig. 6 is a front view of the plate member C;

fig. 7 is a schematic perspective view of a plate C;

FIG. 8 is a schematic view of a wall structure formed by splicing wood frame templates;

FIG. 9 is a sectional view taken along line D-D of FIG. 8;

FIG. 10 is a cross-sectional view taken along line C-C of FIG. 8;

FIG. 11 is a schematic view of three types of pallet means in cooperation with a plate member;

FIG. 12 is a schematic view of a pallet arrangement;

FIG. 13 is a perspective view of the pallet apparatus shown in FIG. 12;

FIG. 14 is a schematic view of a wall form with a boss and a recess cooperatively engaged;

FIG. 15 is a side view of the wall form with the male and female bosses mated together;

FIG. 16 is a schematic view of a reentrant panel construction;

FIG. 17 is a schematic cross-sectional view of a reentrant panel member;

FIG. 18 is a schematic view of the combination of the wood frame formwork with the back edge;

FIG. 19 is a perspective view of the wood frame formwork in combination with the back edge;

FIG. 20 is a sectional view taken along line E-E in FIG. 18;

FIG. 21 is a schematic view of a template building structure of a wooden frame of a sample house;

FIG. 22 is a schematic illustration of a beam sideform configuration;

FIG. 23 is a schematic perspective view of a two-sided template;

FIG. 24 is a schematic perspective view of a bottom beam template;

FIG. 25 is a schematic perspective view of a wooden frame formwork construction structure;

FIG. 26 is a front view of the wooden frame formwork with the clamp attached;

FIG. 27 is a partial cross-sectional structural view of the clamp;

FIG. 28 is a schematic view of a clamp holding bar configuration.

In the figure: 1. a wood frame template; 11. the beam comprises plate members A, 12, plate members B, 13, plate members C, 14, beam bottom templates, 15, beam side templates, 100 and plate members; 101. a front side; 102. back 200, bar 201, groove 202, bottom bar 203, stay 204, bolster, 205, foot form, 210, longitudinal bar 211, first longitudinal bar 212, second longitudinal bar 220, transverse bar 221, first transverse bar 222, second transverse bar 230, joint 231, slot 2311, first side 2312, second side 2313, bottom surface 232, boss 240, mating portion 241, boss 2411, first mating surface 2412, second mating surface 2413, top surface 242, recessed table 300, internal corner plate 310, corner plate 320, corner longitudinal rod 330, corner transverse support 400, pallet means 410, top bar 411, pivot hole 412, wedge 413, connecting rod 414, top bar 415, diagonal support 420, pallet seat 421, pivot shaft 422, receptacle 500, dorsal bar 510, 520. sleeve, 600, clamp, 610, clamp body, 620, clamp arm, 621, clamp table, 622, first clamping surface, 630, mounting arm, 631, slide hole, 632, first through hole, 640, slide block, 641, clamping head, 642, second clamping surface, 643, second through hole, 644, stop, 650, wedge.

Detailed Description

For a further understanding of the invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings and examples. It is to be understood that the examples are illustrative of the invention and not limiting.

The concept of wood in the invention not only comprises solid wood, but also can be composite wood, namely, the natural structure of the wood material is artificially changed, and the wood material with certain physical property meeting the expected requirement is achieved. Can be reinforced composite wood, solid wood composite and other materials, can also be PVC plates, bamboo wood plates, wood slag plates and other similar plates, and all belong to the scope.

As shown in fig. 1 to 7, the wood frame formwork 1 of the present invention includes a plurality of wood-based panels 100, the panels 100 include a front surface 101 and a back surface 102 opposite to each other, the front surface 101 contacts cast-in-place concrete when in use, and bars 200 are distributed around the back surface 102. The bar 200 includes a longitudinal bar 210 and a transverse bar 220, and serves to support and connect and position the panel 100. The transverse bars 220 are respectively disposed at the upper and lower ends of the plate member 100, and the longitudinal bars 210 are disposed at the left and right ends of the plate member 100. The transverse bars 220 are connected to, abutted against or spaced from the top and bottom of the longitudinal bars 210, and the longitudinal bars 210 and the transverse bars 220 form a frame-shaped structure. A stay 203 can be further arranged in the middle of the frame structure, the stay 203 can be transversely arranged or longitudinally arranged, a space is arranged between two sides of the stay 203 and the rods 200 arranged in parallel, and the upper end and the lower end of the stay 203 are respectively abutted against the rods 200 arranged by treatment.

The bar 200 and the plate 100 are preferably bonded together by glue, but the bar 200 may be formed by pressing together when the plate 100 is manufactured. The glue is the existing wood bonding glue. The rod member 200 and the plate member 100 are fixedly connected by glue, and are integrated, so that the structure is firm, and the cutting is convenient. In some embodiments, the bar 200 and plate 100 may also be fixedly attached by fasteners such as screws, bolts, and nails.

Vertical pole 210 is including being located the first vertical pole 211 and the vertical pole 212 of second of plate 100 both sides limit portion, first vertical pole 211 is equipped with joint portion 230 with adjacent 1 concatenation sides of wood frame template, and corresponding vertical pole 212 of second is equipped with and combines portion 230 complex cooperation portion 240, and about or the member of upper and lower on same plate 100 sets up joint portion and cooperation portion respectively, can conveniently splice, and the commonality is strong. Joint portion 230 and cooperation portion 240 respectively can with the corresponding cooperation portion 240 of adjacent wooden frame template 1 and the cooperation of joint portion 230, through the concatenation of pole 200 for the side of adjacent plate 100 can laminate completely, thereby ensures that the positive template plane that forms of plate 100 has sufficient roughness, and then the concatenation seam dislocation is less, and cast-in-place wall surface of building is smooth. Of course, in the splicing of the frame formworks 1, the connecting portions 230 may be provided on the bars 200 of one frame formwork 1, and the fitting portions 240 may be provided on the bars 200 of another adjacent frame formwork 1.

As shown in fig. 8-10, the specific structure of the combining portion 230 is preferably a slot 231 disposed on the outer side (the side in mating contact with the adjacent bar) of the bar 200, the slot 231 is a groove with a trapezoidal cross section and includes a first side 2311 and a second side 2312 opposite to each other, the first side 2311 and the second side 2312 are relatively inclined and have an open mouth shape, and a bottom 2313 is disposed between the first side 2311 and the second side 2312. The corresponding matching portion 240 includes a protrusion 241 matching with the slot 231, the protrusion 241 is a protrusion with a trapezoidal cross section, and includes a first matching surface 2411 and a second matching surface 2412 respectively matching with the first side surface 2311 and the second side surface 2312 in an abutting or contact manner, and a top surface 2413 having a gap with the bottom surface 2313 when the protrusion 241 matches with the slot 231. The insertion groove 231 and the protrusion 241 are respectively penetrated through the longitudinal ends of the side surface of the bar 200. Of course, the first side surface 2311, the second side surface 2312 and the bottom surface 2313 may be flat surfaces or circular arc surfaces, or a part of the first side surface 2311, the second side surface 2312 and the bottom surface 2313 may be circular arc surfaces, or a part of the first side surface 2411, the second side surface 2412 and the top surface 2413 may be circular arc surfaces or prismatic surfaces. The coupling portion 230 and the fitting portion 240 may include one or several insertion grooves 231 and protrusions 241, respectively.

As shown in fig. 11 to 15, it is further preferable that the coupling portion 230 is provided with a projection 232 at a side of the bar 200, and the fitting portion 240 is provided with a recess 242 to be fitted with the projection 232. The side of the bar 200 where the coupling part 230 or the fitting part 240 is provided is a plane, and a portion protruding from one side in the longitudinal direction of the plane is a corresponding concave portion recess 242 of the projection 232. The two bars 200 are spliced together by the matching of the boss 232 and the recess 242 to form a splice joint similar to a 'Z' shape, and after splicing, the movement of any one bar relative to the other bar in a transverse direction is limited. On the basis, in order to make the splicing gap of the plate member 100 smaller and avoid the gap, a supporting plate device 400 can be arranged at the side of the bar arrangement concave table 242, and the supporting plate device 400 is provided with a top rod 410 which is abutted against the bar 200 at the side of the boss 232 matched with the concave table 242 or abutted against the side of the backing plate 204. The backing plate 204 abuts against the bar 200 on the side of the boss 242 or covers the joint seam on one side of the two spliced bars 200. The blade device 400 includes a blade seat 420, and the blade seat 420 is fixed to the bar 200 or the stay 203. The lift pins 410 cooperate with the pallet base 420 to support the bars 200, reducing stagger. The matching form of the top rod 410 and the pallet seat 420 is various, including the mode of pin joint, insertion or welding, bolt and the like for fixed connection.

One form of the pivot-joint of the top rod 410 and the supporting plate seat 420 is: the supporting plate seat 420 is fixed on the rod 200 or the stay 203 through a bolt, the supporting plate seat 420 is provided with a pivot shaft 421 axially perpendicular to the plate 200, the push rod 410 is provided with a pivot hole 411 matched with the pivot shaft 421, and one end of the push rod 410 abuts against the rod 200 or the cushion plate 204 when rotating around a pivot part.

One form of the insertion fit of the top rod 410 and the supporting plate seat 420 is as follows: the supporting plate seat 420 is fixed on the bar 200 or the stay 203 through bolts, and is provided with a jack 422, the top rod 410 is provided with a wedge-shaped part 412, and the wedge-shaped part 412 is matched with the jack 422, so that the top rod 410 tightly pushes against the bar 200 or the backing plate 204. When the wedge-shaped part 412 is matched with the insertion hole 422, a clamping tongue matched with the clamping platform can be arranged for placing and slipping.

One form of the fixed connection between the top rod 410 and the supporting plate seat 420 is as follows: the ejector pin 410 comprises a connecting rod 413 and a jacking rod 414, wherein the connecting rod 413 and the jacking rod 414 are formed by right-angled plates or rods and comprise channel steel, C-shaped steel and the like which are cut or spliced. One end of the connecting rod 413 is connected with the supporting plate seat 420 in a welding mode, one end of the jacking rod 414 extends towards the splicing direction, and the jacking rod 414 and the bar 200 are directly provided with the backing plate 204, so that a supporting plate device 400 can be longer and a part of the supporting plate device can be spliced and have small staggered joints. And an inclined strut 415 is also arranged between the ejector rod 410 and the supporting plate seat 420. In some embodiments, the right-angled top bar 410 may also be hinged to the pallet base 420, the connecting rod 413 is hinged to the top support bar 414, and the diagonal brace 415 is hinged to the top bar 410 or the pallet base 420.

Of course, there are various forms of the matching part 240 and the combining part 230, including the above mentioned slot 231 and the protrusion 241, the boss 232 and the concave 242 with trapezoidal cross section, and may also include matching structures with saw tooth cross section, oval cross section or semicircular cross section.

As shown in fig. 18-21, the transverse bar 220 includes a first transverse bar 221 disposed at an upper end and a second transverse bar 222 disposed at a lower end. In some embodiments, the first and second transverse bars 221, 222 are provided with mating and bonding portions 240, 230, respectively. Therefore, the plate members 100 of this type can be spliced up and down, so that the wooden frame formwork 1 can be spliced more conveniently.

When the wood frame template 1 is spliced left and right, the first longitudinal bar 211 and the adjacent second longitudinal bar 212 are correspondingly spliced, the two longitudinal bars 200 are clamped by the clamp, and the joint part 230 and the matching part 240 are matched, positioned and fixed, so that the dislocation and the gap between the two spliced plates 100 are small.

Similarly, when the wood frame formwork 1 is spliced up and down, the first transverse bar 221 and the second transverse bar 222 above are spliced, and the first transverse bar 221 and the second transverse bar 222 in the up-and-down position are clamped and fixed through the clamping device.

The gap formed by splicing the wood frame formwork 1 between the plate members 100 can be arranged between the two spliced longitudinal bars 210 or the two spliced transverse bars 220, or can be offset to one longitudinal bar 210 or one transverse bar 220.

As shown in fig. 16 and 17, when the wood frame formwork 1 is assembled to form a wall formwork, the corner or the protruding part and the recessed part are connected with the internal corner plate 300, and the internal corner plate 300 comprises a corner plate 310 which forms an included angle of less than 180 degrees, is generally a right angle, and a longitudinal rod 320 and a transverse corner support 330 which are positioned at the inner side (the side with the included angle of less than 180 degrees). The corner longitudinal rods 320 and the corner transverse supports 330 are adhesively or fixedly attached to the corner plate members 310, respectively, and support the corner plate members 310 in the longitudinal and transverse directions, respectively, to provide the desired strength and rigidity. Two longitudinal bars 210 and two transverse bars 220 are respectively adhered to the edge parts of the corner plate member 310, and the longitudinal bars 210 are provided with matching parts 240 or combining parts 230 or the two longitudinal bars 210 are respectively matching parts 240 and combining parts 230. Specifically, the gusset member 310 includes two panels 100 joined at an angle, typically 90 °, and the stay 203 is fixedly connected to the two panels 100 or to the edge of one of the panels 100 at the joint. The angle cross brace 330 has a corresponding angle, two bevel edges are respectively fixedly connected with the two templates, and a gap for placing the stay 203 is reserved at the top. The angular lateral supports 330 are provided in number at intervals.

As shown in fig. 21 and 15, when the external corner is assembled by the wood frame formwork 1, the external corner can be assembled by a designated external corner formwork, or two wood frame formworks 1 can be assembled in a right angle and fixed by a back ridge 500. The bar 200 on one side of the external corner may present a protruding portion of the plate 100 where a junction or mating portion is formed toward the front of the plate 100 to mate with the bar 200 on the other side of the external corner. Of course, the bars at the external corners may also be offset or not in contact. The external corner template can be formed by pre-assembling and fixing the bars and the plates, and transverse and longitudinal corner fixing and supporting structures can be arranged at the corners of the external corner template.

When the wall external wood frame formwork and the wall internal wood frame formwork are assembled and installed in a large area, the wood frame formwork 1 needs to be fixedly clamped through back ridges 500 which are oppositely arranged on the side of the wall external wood frame formwork and the side of the wall internal wood frame formwork, the back ridges 500 on the two sides are connected through a connecting rod 510, the connecting rod 510 penetrates through the oppositely arranged wood frame formwork 1 and a sleeve 520 is arranged between the wood frame formworks, and the thickness of a poured concrete wall is limited by the sleeve 520 abutting against the wood frame formwork 1.

For the convenience of assembly and modular design, the cross section of the bar 200 is preferably a rectangular wood strip with the side length of 30mm-70mm, the wood frame template 1 comprises a plate A11 and a plate B12 with the height of 0.5m-5m, the width of the plate A11 is 120mm-280mm, two sides of the plate A11 are spliced and connected with the plate B12, and the connecting rod 520 penetrates through the plate A11. The width of the plate B12 is 210mm-800mm, for example, the plate B12 comprises a conventional size of plate 200 with a width of 600mm, a brace 203 is longitudinally and fixedly arranged on the back of the plate 200 in the area enclosed by the bars 200, and the width of the non-conventional plate 200 is adjusted according to different wall width requirements, although the non-conventional plate 200 may or may not be provided with a brace.

The upper end of the wall outer wood frame template 1 is spliced and connected with a plate C13, the height of the plate C13 is 120mm-800mm, the width of the plate C13 is 0.5m-5m, and a plurality of supporting strips are fixedly arranged in the area surrounded by the rods 200 at intervals in the longitudinal direction. The wall outer wood frame template 1 is formed by splicing a plate A11 and a plate B12 into a wall surface template between each floor height, the templates of the thickness parts of the floor boards are spliced with the end parts of the plate A11 and the plate B12 through a plate C13, the wall outer wood frame template at one floor comprises a plate A11 and a plate B12, and the lower end and the upper end of the plate A11 and the plate B12 are respectively connected with a plate C13. The wall body and the floor or the beam can be poured simultaneously, after the cast-in-place wall body is maintained to meet the requirement, the plate C13 at the lower ends of the plate A11 and the plate B12 is firstly removed, then the plate A11 and the plate B12 are removed, the removed wood frame template 1 is used as a template of an upper floor for splicing and building, the turnover rate is sequentially and circularly improved, and the using amount of the wood frame template is reduced. The door and window openings of the poured wall are spliced by cutting the plate A11 and the plate B12 or the preset wooden frame template 1 with unconventional height.

The pole of 1 upper end of wood frame template is inconsistent with the template tip of dismantling steel bar truss building carrier plate in the wall, and building carrier plate tip also can set up the sheet steel angle steel and bordure and make the reentrant corner of building carrier plate and wall body of pouring better. The first floor of the lower end of the wooden form 1 is generally provided with a foot form 205.

As shown in fig. 26 to 28, the clamp 600 for connecting adjacent bars 200 comprises a clamp body 610, wherein one end of the clamp body 610 is provided with a protruding clamping arm 620, the other end is provided with a mounting arm 630, the clamping arm 620 is provided with a clamping table 621 on the side opposite to the mounting arm 630, and the clamping table 621 is provided with a first clamping surface 622. The mounting arm 630 is provided with a slide hole 631 axially perpendicular to the clamping arm 620, a slide block 640 is fittingly mounted in the slide hole 631, and the slide block 640 can slide in the slide hole 631 relative to the clamping arm 620. Of course, the sliding block 640 may be a pipe, a rod, or a block. One end of the sliding block 640 is provided with a clamping head 641, and the other end is provided with a boss-shaped or detachably mounted stop head 644. The clamping head 641 is provided with a second clamping surface 642 opposite the first clamping surface 622. The two clamping surfaces are relatively parallel and in the same line of travel as the slide 640. Preferably, the stop 644 and the clamping head 641 are interchangeable, and both can be used as a stop end boss for stopping the slider 640 from falling out of the slide hole 631, and can also be used as an interference part for clamping an intermediate object. The mounting arm 630 is provided with a first through hole 632 penetrating through the sliding hole 631, and the slider 640 is correspondingly provided with a second through hole 643 penetrating through the slider 640. When the clamp 600 is used, the first clamping surface 622 and the second clamping surface 642 abut against two sides of the two mating bars 200, the first through hole 632 and the second through hole 643 are staggered, and the wedge 650 partially penetrates through the first through hole 632 and the second through hole 643 to reduce the staggered parts of the two through holes, so that the slider 640 is pushed to move to clamp the two bars 200. The wedge 650 is a right angle wedge structure, and includes two right angle sides and a bevel side. The right-angled edge at the upper end of the wedge 650 is the hammering end. When the clamp 600 is used for clamping two bars 200, the groove 201 can be arranged on the bar 200 at the position where the first clamping surface 622 and the second clamping surface 642 contact the bar 200, and the groove 201 enables the clamping table 621 and the clamping head 641 to be partially trapped in the groove, so that the sliding of the clamp 600 is reduced, the accurate positioning is ensured, and the clamping is firm.

As shown in fig. 22 to 25, the wood frame formwork 1 is applied to a beam formwork including a beam bottom formwork 14 and a beam side formwork 15 of a beam bottom. The side of the bars 200 at the periphery of the beam bottom formwork 14 is provided with a joint part 230, and the bottom bars 202 at the bottom of the beam side formwork 15, which are matched with the bars 200 of the beam bottom formwork 14, protrude out of the plate part 100 of the beam side formwork 15. The bottom bar 202 is provided with a mating portion 240 on the front side facing the plate member 100. The beam bottom template 14 and the beam side template 15 are spliced in a matched mode, and the split joint is quick and small. Further, the lower ends of the bottom bars 202 are located at the same level as the lower ends of the beam bottom forms 14, so that the beam bottom forms 14 and the bottom bars 202 can be supported at the same time in the support structure of the beam bottom forms, and the support structure can be simplified.

The present invention and its embodiments have been described above schematically, without limitation, and what is shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. Therefore, if the person skilled in the art receives the teaching, without departing from the spirit of the invention, the person skilled in the art shall not inventively design the similar structural modes and embodiments to the technical solution, but shall fall within the scope of the invention.

Claims (10)

1. The utility model provides a wooden frame plate for concrete placement which characterized in that includes wooden class rectangle plate, and this plate is including being used for with the front of concreting contact to and the fixed back that is provided with the pole, the pole distributes in the peripheral position on the plate back.

2. A timber frame panel for concrete pouring according to claim 1 wherein at least one side of the bar is flush with a side of the panel.

3. A timber frame plate for concrete pouring according to claim 1, wherein the bar portions project beyond the sides of the plate or the corresponding sides of the plate project beyond the bars.

4. A timber frame panel for concrete pouring according to any one of claims 1 to 3, wherein the bars are provided with engaging or cooperating portions adjacent the sides of the edges of the panel.

5. A timber frame plate for concrete pouring according to claim 4 wherein the engaging portion is provided with a socket and the engaging portion is provided with a projection which is locatable in cooperation with the socket.

6. A timber frame plate for concrete pouring according to claim 5 wherein the socket includes a base and the projection includes a top, the base and top having a gap when the socket engages the projection.

7. The concrete pouring plank of claim 6 wherein the cross-sections of the slots and lugs are trapezoidal or the cross-sections of the slots and lugs are castellated.

8. The concrete pouring wooden frame plate member as recited in claim 4, wherein said engaging portion includes a boss protruding on a side of the bar, and said engaging portion engages with a recessed land of the boss.

9. A timber frame plate for concrete pouring according to claim 1, wherein longitudinal or transverse stays are fixedly provided on the rear surface of the plate member within the range surrounded by the peripheral rails of the plate member.

10. A timber frame plate for concrete pouring according to claim 4, wherein the bar includes a groove provided on the opposite side of the engaging or fitting portion.

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