TR2024011663A2 - Production Moulds for Linear, Serial Cutting of New Design Aerated Concrete Production Blocks in X-Axis Positive Direction, Y-Axis Positive Direction and Z-Axis Negative Direction - Google Patents

Abstract

Production Molds for Linear, Serial Cutting of New Design Aerated Concrete Production Blocks in the Positive Direction of the X Axis, the Positive Direction of the Y Axis and the Negative Direction of the Z Axis My invention makes the upper surfaces of the new design aerated concrete blocks, which are not suitable for linear cutting and for which I have previously patented, square or rectangular in surface, suitable for the linear cutting techniques used in today's aerated concrete production, by means of removable spacer molds (2) while they are still in the production mold (1) stage. The shape of the aerated concrete element is created by placing removable spacer molds (2) specially prepared for each aerated concrete element in appropriate places inside the production mold (1). For example, when 4 square prism shaped spacer removable molds (2) are placed in the areas between the arms of the + shaped connector, the aerated concrete element mold will be formed in this area by itself and will give a square-shaped appearance with them. After the mold is poured, these removable spacer molds (1) are removed from the production mold (1). The resulting aerated concrete elements are + shaped. From the ends of the arms of this + shaped aerated concrete block, parallel to the positive X axis and parallel to the positive Y axis, linear cuts can be easily made from end to end and can be easily separated into individual blocks. There is no aerated concrete loss; economical cuts are made; mass production is done.

Description

DESCRIPTION Production Molds for Linear, Serial Cutting of New Design Aerated Concrete Production Blocks in the Positive X-Axis, Positive Y-Axis and Negative Z-Axis Direction Technical Field The invention relates to the construction of production molds that will enable the mass production of new aerated concrete production blocks having shapes different from rectangular prism and square prism and to the cutting of the main production blocks produced. State of the Art Today, only the aerated concrete poured into a rectangular prism mold is cut in layers from the top parallel to the positive OX-axis and parallel to the positive OY-axis, and from the sides along the negative OZ-axis, to obtain classical flat blocks in the shape of a rectangular prism. For this reason, flat block, hollow block, lintel, etc. For every need such as, attempts are made to use aerated concrete blocks produced in different sizes of rectangular prisms. Purpose of the Invention To make production molds (1) that can mass-produce different shaped aerated concrete elements, which are difficult to mass-produce with today's production mold and cutting techniques, and to turn the main aerated concrete blocks produced into single blocks that can be used in construction by making linear cuts parallel to the positive direction of the OX axis, parallel to the positive direction of the OY axis and in the negative direction of the OZ axis used in today's production technique. . . I adapted the cutting of the new design aerated concrete elements in my patent with today's cutting techniques, with removable molds (2) that create gaps, to the linear cutting technique in the positive direction of the OX axis and in the positive direction of the OY axis, while still in the preparation phase of the production mold (1). So much so that the cutting device will never rotate around the curvature of the aerated concrete element, but will always make linear cuts, as it does today. The basis of the invention is based on the ability to always complete the shape of the newly designed aerated concrete element in a square or rectangle using removable molds (2) that create gaps. Current linear cutting lines can be easily passed along the edges of these symmetrical squares or rectangles, created (drawn) parallel to the positive OX axis or the positive OY axis using the mirror command in the AutoCAD technical drawing program. Explanation of the Shapes Preliminary Remarks: While drawing the shapes, I did not draw some of the overlapping lines to avoid confusion in the drawing. In Figure 2, the image of the removable formwork (3) with a rigid metal bar cage (7) that stabilizes the removable formwork is shown in the drawing of the production formwork (1) of the L-shaped connectors (5), T-shaped connectors (13) and +-shaped connectors (14). Since it does not contribute to the drawing, I have drawn it as an example in each connector only. Generally, I have drawn 2 aerated concrete elements in the positive direction of the OY axis and 2-4 in the positive direction of the OX axis in a row. Of course, this number can be easily increased with the "mirror" command in technical drawing programs and the production formwork (1) can be made in the direction of that drawing, thus accelerating the production. In the production formwork (1), the space generator can be drawn in the Although there is no space between the inner edges of the mold (2) and the production mold (1), I drew the lines slightly apart in order not to overlap. Instead of hatching, I wrote the shape code 2" inside the shapes of all the removable molds (2) that create the space. In each picture, I hatched the inside of one of the aerated concrete elements with L-shaped lines. To simplify the explanation in my description, I took the R3 coordinate system as a reference. I explained the positions with the OX, OY and OZ axes, with the upper left corner of the production mold (1) as the origin (O), the upper right corner as Y+, the lower left corner as X+ and the lower left base corner of the production mold (1) as Z-. I accepted the face adjacent to the OY axis as the front face and the face at the end of the OX axis positive direction as the back face. Explanation of the shapes: Figure 1: Top view of the multi-layer production mold (1) of the L-shaped connector (5) with vertical beam spacers (3). .. Figure 2: Top view of the multi-layer production mold (1) of the L-shaped connector (5) with a removable spacer mold (2) and a rigid metal bar cage (6). . . Figure 3: Top view of the multi-layer production mould (1) of the screw-hole base (10) of the production mould, fixing the spacer removable moulds (2) of the L-shaped connector (5) to the base of the production mould (1)... Figure 4: Top view of the multi-layer production mould (1) of the T-shaped connector (13) with vertical beam gap (3)... Figure 5: Multi-layer production mould (1) of the vertical beam gap (3) + shaped connector (14) A- Top view of the multi-layer production mould (1)... B- Vertical section of the spacer removable mould (2) with cover Figure 6: Top view of the multi-layer production mould (1) of the stepped flat block (15)... Figure 7: Two different designs of multi-storey production mould (1) for unreinforced lintel (18)... A- Production mould (1) in which two side by side unreinforced lintels (18), space forming removable moulds (2) are common and positioned in the middle... B- Two side by side unreinforced lintels (18), space forming removable moulds (2) are separate and on the sides of the production mould (1) Figure 8: Top view of single storey production mould (1) for reinforced lintel (22)... Figure 9: Top view of multi-storey production mould (1) for single walled flat block with foam filling region (23)... Figure 10: Top view of two different designs of multi-storey production mould (1) for double walled flat block with foam filling region (25)... ... A- Production mould (1) with removable mould for joint spacer (2) B- Production mould (1) with removable mould for separate spacer (2) (1) Top view of the multi-layer production mould (1) for the horizontal beam forming U block (26) ... Top view of the multi-layer production mould (1) for the flat block with rounded ends (27) for half wall ... Top view of the multi-layer production mould (1) for the block with wide top for the upper row of half wall ... Top view of the multi-layer production mould (1) for the flat block with skirting on both sides (31) ... Top view of the multi-layer production mould (1) for the flat block with skirting on one side (33) ... Internal stepped arm connection for double wall panel (35) and stepless arm connection for double wall panel (36) Top view of multi-storey production mould (1)... Internal stepped beam connection for double wall panel (38) and non-stepped beam connection for double wall panel (39) Top view of multi-storey production mould (1)... Internal stepped base connection for double wall panel (40) and non-stepped base connection for double wall panel (41) Top view of multi-storey production mould (1)... Figure 19: Right side, left side and top views of the bottom row, middle rows and top row of the L connection plate system (Figures A, B and C of this picture are pictures in which the blocks are shown as if they are divided into two imaginary halves to facilitate explanation, but in fact each of the blocks in A, B and C are monoblock structures. A- Lower half of the lower row of the L connection plate system (46) and the lower half of the lower row of the L connection plate system ... B- Front view (from the side adjacent to the column) of the lower half (49) of the middle rows of the L connection plate system, the upper half (51) of the middle rows of the L connection plate system and the horizontal arm entry gap (50) of the middle rows of the L connection plate system ... C- Front view (from the side adjacent to the column) of the upper row (52) of the L connection plate system and the bearing of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system and in the lower half of the middle rows ... D- Top view of the flat block with L connection plate (42) ... Figure 20: Multi-layer production of the upper row block (52) of the flat block with L connection plate (42) A: Vertical of the L connection plate extending in the lower half of the upper row of the L connection plate system ... B: Front view of the stopper (56) of the bed forming apparatus which will form the bed of the vertical extension of the L connection plate ... C: Right side and left side views of the entry gap (54) of the bed forming apparatus of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system ... Right side and left side views of the single-layer production mold (1) of the lower half of the lower row of the L connection plate system (46) and the upper half of the lower row of the L connection plate system (48) ... Copied with the Mirror command, two rows in the positive direction of the Y axis and many rows in the positive direction of the X axis ... Figure 22: Lower half of the middle rows of the L connection plate system (49) and right side and left side views of the single-layer production mold (1) belonging to the upper half of the middle rows (51) of the L-shaped connection plate system... Two rows in the positive direction of the Y-axis and several rows in the positive direction of the X-axis copied with the Mirror command... Figure 23: Top view of the removable mold (60) for reducing the width of the production mold and the removable mold (62) for reducing the width of the production mold. . . Figure 24: Top view of the additional metallic plate (66) placed on the base of the production mold, which contains the holes for the fixing screws (2) for the removable molds (5) creating the space of the L-shaped connector to the base of the production mold (1)... Explanation of Reference Numbers in Figures Production mold (1) (Figure 1) Vertical beam gap Removable formwork (3) (Figure 1) Screw holes on the top of the removable formwork (4) L-shaped connector (5) (Figure 1) Longitudinal and cross-sectional block cutting lines (6) (Figure 1) Rigid metal bar cage fixing the removable formwork (7) (Figure 2) Rigid metallic plates with screw holes on the rigid metal bars (8) (Figure 2) Vertical beam gap Removable formwork rigid metallic plate with screw holes (9) (Figure 2) Screw hole base of the production formwork (10) (Figure 3) Areas on the bottom of the production formwork with screw holes to fix the removable formwork (11) (Figure 3) Screw holes on the base of the production mold with screw holes (12) (Figure 3) T-shaped connector (13) (Figure 4) + shaped connector (14) (Figure 5) Flat block with steps (15) (Figure 6) Lower step (16) (Figure 6) Upper step (17) (Figure 6) Arms of the lintel (19) (Figure 7) Reinforcement (20) (Figure 8) Holes for screws to fix the reinforcement (21) (Figure 8) Lintel with reinforcement (22) (Figure 8) Single-wall flat block with foam filling area (23) (Figure 9) Single wall (24) (Figure 9) Double-wall flat block with foam filling area (25) (Figure 10) Horizontal line forming U block (26) (Figure 11) Flat block with rounded ends for half wall (27) (Figure 12) A removable mould for creating a gap (28) (Figure 12) A removable mould for creating a gap between two flat blocks with rounded ends for half wall (29) (Figure 12) A wide top block for the top row of half wall (30) (Figure 13) Flat block with skirting on both sides (31) (Figure 14) Double-sided skirting (32) (Figure 14) Flat block with skirting on one side (33) (Figure 15) Single-sided skirting (34) (Figure 15) Internal stepped column connection for double wall panel (35) (Figure 16) Non-stepped column connection for double wall panel (36) (Figure 16) Internal step of column connection for double wall panel (37) (Figures 16, 17, 18) Internal step beam connection for double wall panel (38) (Figure 17) Non-step beam connection for double wall panel (39) (Figure 17) Internal step base connection for double wall panel (40) (Figure 18) Non-step base connection for double wall panel (41) (Figure 18) Flat block with L connection plate (42) (Figure 19 D) Horizontal arm of L connection plate (43) (Figure 19 D, 21, 22) Vertical arm of L connection plate (44) (Figure 19 D, 21, 22) Aerated concrete mortar passage holes on the horizontal arm of L connection plate (45) (Figure 19 D) System with L connection plate Lower half of the lower row (46) (Figure 19 A, Figure 21) The bearing in which the vertical arm of the L connection plate extends in the upper half of the lower row and the upper half of the middle rows (47) (Figure 19 A and B) Upper half of the lower row of the L connection plate system (48) (Figure 19 A, Figure 21) Lower half of the middle rows of the L connection plate system (49) (Figure 19 B, Figure 22) Horizontal arm inlet of the middle rows and the lower row of the L connection plate system Upper half of the middle rows of the L connection plate system (51) (Figure 19 B, Figure L connection plate system upper row (52) (Figure 19 C) The L connection plate extending in the lower half of the upper row of the L connection plate system and the lower half of the middle rows the bearing of the vertical arm of the connection plate (53) (Figure 19 B) the entry opening of the device forming the bearing of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system (54) (Figure 20 C) the top view of the device forming the bearing of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system in the production block (55) (Figure 20 A) the stopper of the bearing forming device (56) (Figure 20 B) the bearing forming metallic extension plate of the bearing forming device (57) (Figure 20 A and B) the plate-shaped elevation to which the end of the vertical arm of the L connection plate is screwed on the upper edge of the production mold (58) (Figure 21, 22) the screw holes for the vertical arm of the L connection plate to be screwed to the column (59) Removable mold to reduce the width of the production mold (60) (Figure 23) Inner-upper edge of the removable mold to reduce the width of the production mold (61) Removable mold to reduce the length of the production mold (62) (Figure 23) In the upper row of L-shaped connection plate systems, bearing to form the bearing of the vertical extension of the L-shaped connection plate Screw holes of the forming apparatus (63) (Figure 20 B) In the middle row of L-shaped connection plate systems, bearing to form the bearing of the vertical extension of the L-shaped connection plate removable metal plate (64) (Figure 22) In the middle row of L-shaped connection plate systems, bearing to form the bearing of the vertical extension of the L-shaped connection plate, Screw holes on the removable metal plate (65) (Figure 22) Additional metallic plate placed on the base of the production mold (66) (Figure 24) Areas on the additional metallic plate to which the removable cavity forming molds will be fixed (67) (Figure 24) Screw holes on the additional metallic plate (68) (Figure 24) Removable cavity forming mold with quarter ellipse curvature at the ends (69) Removable cavity forming mold with half ellipse curvature at the ends (70) (Figure Removable cover of cavity forming molds (71) Removable cavity forming mold to reduce the depth of the production mold (72) Bottom row of the L connection plate system (73) (Figure 19)Middle part of the L connection plate system rows (74) (Figure 19) Explanation of the Invention Shape of the Devices, Functions of the Parts in the System Production mold (1) (Figure 1): It is in the shape of a rectangular prism with an open top. Its width, length and height vary depending on the shape of the aerated concrete element to be produced, how many aerated concrete elements will be produced in the positive direction of the OX axis and the positive direction of the OY axis, and how many layers will be produced in the negative direction of the OZ axis. In the production of reinforced aerated concrete elements, generally single-layer production molds (1) are used. The side walls of the production mold (1), except for the upper row (52) of the L connection plate system, are in the shape of a flat plate and are fixed. The upper row (52) of the L-connection plate system is provided with slots (54) on the right and left side walls of the production mold (1) for the bearing of the forming device, which is located in the lower half of the upper row of the L-connection plate system, and for the bearing of the vertical arm of the L-connection plate, which extends along the lower half of the upper row of the L-connection plate system. A rigid metal bar cage (7) is placed on the production mold (1) to secure the removable molds. For economic reasons, a removable mold (60) can be placed inside the main mold, along the positive direction of the OX axis, to narrow the width of the production mold and use it in the production of different aerated concrete elements. Again, along the positive direction of the OY axis, transversely, a removable spacer mold (62) can be placed to shorten the length of the production mold. The base of the production mold (1) contains screw holes for screwing the removable spacer molds (2). If the production mold (1) is to be used in the production of different aerated concrete blocks, an additional metallic plate (66) is placed on the base of the production mold (1), which is placed on the base of the production mold (1) for each different shaped aerated concrete block. Figures 16, 17, and 18: The shapes of the aerated concrete elements in the production mold (1) are created by placing the removable spacer molds (2) in appropriate locations on the production mold (1). They are very useful. Its other function is to complete the shape of the top surface of the aerated concrete element into a square or rectangle, making it suitable for linear cuts made in the positive X-axis and positive Y-axis directions. There are no gaps between the walls of these molds and the walls of the production mold, and there is a tight contact that prevents the aerated concrete mortar from entering. In the technical drawings, I have drawn the lines as if there were a gap between them to prevent overlapping. Screw holes are provided in the base of the production mold (1) to secure these molds to the base. Their tops are open to facilitate screwing. They are made of rigid metal to prevent stretching or deformation during the pouring of the aerated concrete mortar. Larger molds may contain metallic bars in +, X-shaped, or caged shapes. The placement of these bars is spaced sufficiently so as not to hinder the screwing process at the base. Among the aerated concrete element blocks, their upper sections are square or rectangular and in the shape of a square prism or rectangular prism except for those used in the production of aerated concrete elements called flat block with rounded ends for half wall (2-7), block with wide top side for the top row of half wall (30), internal stepped arm connection for double wall panel (35), non-stepped arm connection for double wall panel (36), internal stepped beam connection for double wall panel (38), non-stepped beam connection for double wall panel (39), internal stepped base connection for double wall panel (40), non-stepped base connection for double wall panel (41), which are used in the production of aerated concrete elements. The shape of the removable spacer molds (2) used in the production of the aerated concrete elements listed above does not present any difficulties in cutting the blocks. They are taller than the production mold (1) to prevent the aerated concrete mortar from filling the mold during pouring. They are rigid enough to prevent flexing during pouring. For this purpose, rigid metal bars are placed in a + or X-shaped pattern or parallel to each other at various heights of the interior walls, so as not to hinder screwing operations. Removable spacer molds (2), with square or rectangular upper surfaces, can be positioned singly, in monoblocks, or in groups of four, with the cutting lines passing linearly along the edges to ensure rigidity. There are holding bars near the upper sections to facilitate their removal from the production mold (1). Removal is done by hand or by holding these parts. There are screw holes on their bases for the screws to fix them to the base of the production mold (1) to prevent displacement during the pouring of the aerated concrete mortar. The positions of these screw holes are compatible with the screw holes (12) on the screw hole base of the production mold below them, or with the screw holes (68) on the additional metallic plate (66) placed on the base of the production mold; they are aligned and identical. A rigid metal bar cage (7) is placed on top of the removable molds to secure them. There are screw holes (8) in the middle of the upper edges, except for the edges adjacent to the production mold (1). These holes are used to assemble the removable molds with a rigid metal bar cage (7) that contains screw holes in areas compatible with these holes. Essentially, the removable formwork (3) for creating vertical beam gaps in figure 1, the removable formwork (28) for creating gaps placed in the corner areas of the flat block production molds with rounded ends for half walls in figure 12, the removable formwork (29) for creating gaps between two flat blocks with rounded ends for half walls, the removable formwork with quarter ellipse curvature at the ends in figure 13, the removable formwork (69) for creating gaps with half ellipse curvature at the ends in figure 13, the removable formwork (70) for reducing the width of the production mold, the removable formwork (60) for reducing the length of the production mold, and the removable forms (62) for shortening the length of the production mold are multi-use, space-forming devices that perform similar functions. These are molds. In my application, I chose this naming and notation to simplify explanation. The removable cover (71) of the cavity forming molds may also be present on them. In this case, there are screw holes (8) in the center of the upper edges of the covers, excluding the edges adjacent to the production mold (1). These holes are connected to a rigid metal bar cage (7) that secures the removable molds, which contain screw holes in areas compatible with these holes. If the cavity forming mold is to be used with the removable cover (71) of the cavity forming mold, there are screw holes on the sides of the upper edges. The removable cover (71) of the cavity forming mold is fixed to the cavity forming mold by screwing it through these holes. Vertical Beam Gap Forming Removable mold (3) (Figure 1): This mold is used if a vertical bond beam gap is to be created in the production of L, T, and +-shaped connectors. The surface shape of this mold also varies depending on the shape of the bond beam gap. In Figures 1, 4, and 5, I have drawn a removable mold (3), which creates a vertical bond beam gap, symbolically and in a single block, in a cylindrical shape. Its height is slightly higher than the production mold to prevent the aerated concrete mortar from filling the mold during pouring. There are screw holes at the bottom to allow screws to be inserted to secure it to the base of the production mold (1) to prevent displacement during pouring of the aerated concrete mortar. The positions of these screw holes are shown in the figure below the screw hole base of the production mold (10). The screw holes (12) on the base or the screw holes (68) on the additional metallic plate (66) placed on the base of the production mould are aligned and matched. The rigid metal bar cage (7) securing the removable moulds is placed on them. On their upper part, there is the rigid metal plate (9) with screw holes of the removable mould creating the vertical beam gap. These holes are connected to the rigid metal plates (8) with screw holes on the rigid metal bars of the rigid metal bar cage (7) securing the removable moulds in areas compatible with these holes. There are holding bars near the upper parts to facilitate the process of removing them from the production mould. Removal is done by hand or by holding these parts. On their upper part, there are the space forming The molds may also have removable covers (71). In this case, there are screw holes (8) on the upper surfaces of the covers and in the upper side edge areas. These holes are connected to the removable molds with a rigid metal bar cage (7) that secures them and to the vertical cavity forming removable mold (3) in areas compatible with these holes. It is very useful. Screw holes (4) on the upper part of the removable cavity forming molds (Figure 1): The removable cavity forming molds (2), the removable cavity forming mold (3) and the other cavity forming molds that I mentioned in the paragraph I started with "essentially" on page 14 are located in the middle sections of the edges that are not adjacent to the edges of the production mold (1). These holes are located in the middle sections of the edges that are not adjacent to the edges of the production mold (1). The rigid metal bar cages (7) that secure the removable molds, specially made for the mold, are compatible with the screw holes; they are aligned and identical. It is a masonry element shape that I have obtained. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Longitudinal and transverse block cutting lines (6) (Figure 1): These are the cutting lines to be made to obtain the aerated concrete elements one by one after the block is produced. These are the cutting lines made parallel to the positive direction of the OX axis and the positive direction of the OY axis, where the mirror command is applied in the technical drawing. Rigid metal bar cages that secure the removable molds (7) (Figure 2): The cage used to secure the removable molds (2), which create the vertical space, from the top. These bars are metallic bars. There are rigid metal plates (8) with screw holes on the horizontal rigid metal bars located at the midpoints of the edges of these bars and a rigid metal plate (9) with screw holes of the removable formwork that creates vertical beam gaps. These screw holes are connected to the removable formwork (2) that contains screw holes in the areas compatible with these holes and the removable formwork (3) that creates vertical beam gaps. The shape of these cages and the transition lines of the bars are different in the production of each aerated concrete element. Since the cavity-forming molds are higher than the production mold (1) and this cage is placed on them, they are naturally positioned higher than the production mold (1). The bar structure in Figure 2 is similar to the L-shaped connector (5) in Figure 1. For example, it is designed for the formwork (1). Rigid metal plates with screw holes (8) on rigid metal bars (Figure 2): These are located on the rigid metal bar cages (7) that fix the removable forms. They have screw holes on them. These screws pass through these screw holes and enter the screw holes (4) on the upper part of the removable formwork, which are located on the upper edges of the removable formwork below, to immobilize the removable formwork. Rigid metal plate with screw holes (9) of the removable formwork for vertical beam spacers (Figure 2): These are rigid metal plates with screw holes (8) on the rigid metal bars located on the upper part of the removable formwork for vertical beam spacers (3). They have screw holes on them. holes are provided. The screw hole base of the production mold (10) (Figure 3): A single type of aerated concrete element will be produced and removable molds (2), vertical beam gap forming removable molds (3), flat blocks with rounded ends for half-walls placed in the corner areas of the production molds (28), the gap between two flat blocks with rounded ends for half-walls (29), removable molds (60) to reduce the width of the production mold, removable mold (62) to shorten the length of the production mold, removable mold (69) to shorten the length ... The base of the production molds (1) in which the removable molds with curved cavities (70) are located has this structure. The base of the production molds (1) of L-connection plate systems, where these structures are not used, does not have screw holes. On the base of the production mold with screw holes (10), there are areas (11) where the removable molds with cavities will be fixed and the screw holes (12) on the base of the production mold with screw holes. The areas (11) where the removable molds with cavities will be fixed on the base of the production mold with screw holes (Figure 3): These areas and therefore the positions of the screw holes on them are different in the production of each different aerated concrete element. Screw holes on the base of the production mold with screw holes (12) (Figure 3): The locations of the screw holes on the screw-hole base (10) of the production mold vary in the production of each different aerated concrete element; the screw holes in the base of the removable molds are positioned in accordance with the areas where the space-forming molds will be placed; they are aligned and identical. It is a masonry element shape that I have patented. Therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a masonry element shape that I have patented. Therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a masonry element shape that I have patented. Therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. Sub-step (16) (Figure 6): Step This structure, which is a section of the flat block (11), is a structure I have patented with my patent number TR 2021 00599 B; therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. Upper step (17) (Figure 6): This structure, which is a section of the stepped flat block (11), is a structure I have patented with my patent number TR 2021 00599 B; therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a shape of a masonry element that I have obtained. Therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a section of a masonry element that I have obtained. Therefore, I have mentioned it here not to patent it, but to facilitate explanation and increase understanding. I mentioned it here to increase it. The length of the lintel's arms is twice the height of the flat blocks to be used in the area. It is a piece of masonry element. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. The holes for the screws to fix the reinforcement (21) (Figure 8): The screws to be inserted here come through the rigid metal bar cage (6) that secures the removable molds. These special screws, pre-adjusted in length, serve to keep the reinforcement stable in horizontal and vertical planes. It is a form of masonry element that I have taken. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. The only thing not included in that patent is the holes for the screws to fix the reinforcement, which I have indicated with the number 21 on this reinforcement. are the holes (21). I will emphasize and demand this in my requests. Single-wall flat block with foam filler area (23) (Figure 9): It is a flat block without a wall on one side face of the foam filler area. There is a single wall (20) on the other side face. Its advantage is that the foam application can be done after the row is built. Single wall (24) (Figure 9): It is the wall on one side face of the single-wall flat block with foam filler area (23). It is a masonry element shape that I have patented with my patent number. Therefore, I mentioned it here to facilitate explanation and increase understanding, not to obtain its patent. The walls forming the double walls are on both side faces of the block. It is a masonry element shape that I have patented with my patent. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a masonry element shape that I have patented with my patent number B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Removable cavity-forming mold (28) (Figure 12) placed in the corner areas of flat block production molds with rounded ends for half-walls: It is located at the four corners of the production mold, between the flat block with rounded ends for half-walls (2 7) and the production mold (1). It is a removable cavity-forming mold that is not rectangular or square-shaped and has screw holes in its base. On the upper 10 edges, there are rigid metallic plates with screw holes (4) on the upper part of the removable spacer molds to ensure immobilization and to connect them to the metal bar cage. The removable spacer molds can also have a removable cover (71) on top. In this case, there are screw holes (8) on the upper surfaces of the covers. These holes are used to connect the removable molds, which contain screw holes in the areas compatible with these holes, to the rigid metal bar cage (7). It is very useful. Removable spacer mold (29) between two flat blocks with rounded ends for a half wall (Figure 12): It is a removable spacer mold that is not rectangular or square in shape and has screw holes on its base. The figure shown as number 28 is a copy of the cavity-forming mold, copied with the "mirror" command. The upper edges contain rigid metallic plates with screw holes (4) on the top of the removable cavity-forming molds, which will connect them to the metal bar cage for immobilization. The cavity-forming molds may also have removable covers (71) on top. In this case, the covers have screw holes (8) on their upper surfaces. These holes are used to connect the removable molds, which contain screw holes in areas compatible with these holes, to the rigid metal bar cage (7) that secures them. It is very useful. It is a masonry element form that I patented with my patent number B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a masonry element shape that I have patented with my patent. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. At the bottom of the block, there is a two-sided skirting board (32). It is a masonry element shape that I have patented. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is located in the flat block with two-sided skirting board (31). It is a masonry element shape that I have patented with my patent. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is a masonry element shape that I have patented. Therefore, I mentioned it here not to patent it, but to simplify explanation and increase understanding. It is found in the flat block with a skirting on one side (33). Internal stepped column connection for double wall panel (35) (Figure 16): It is an aerated concrete element shape that I patented with my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to simplify explanation and increase understanding. At the ends of the arms, there are two inner steps (3 7) of the column connection for the double wall panel on which the double wall panels fit. The internal step spacing of two adjacent blocks with the mirror command applied along the positive direction of the Y axis is common in the picture. During the cutting process, a cut is made in the center of this common space, parallel to the positive direction of the OX axis, separating this space and the larger space it forms as a monoblock. Stepless column connection for double wall panel (36) (Figure 16): This is an aerated concrete element shape that I patented under my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Internal step of column connection for double wall panel (37) (Figure 16 is the internal step section of the element. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Internal step beam connection for double wall panel (38) (Figure 17): It is an aerated concrete element shape that I patented with my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Non-step beam connection for double wall panel (39) (Figure 17): It is an aerated concrete element shape that I patented with my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. I mentioned it here for. Internal stepped base connection for double wall panel (40) (Figure 18): It is an aerated concrete element shape that I have patented with my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Stepless base connection for double wall panel (41) (Figure 18): It is an aerated concrete element shape that I have patented with my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. It is an aerated concrete element shape that I have patented with my patent. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. They are flat blocks. In Figures 19 A and B, I drew them as two separate blocks on top of each other to facilitate explanation. The original is a single monoblock. It is an aerated concrete element shape that I have patented with my patent number. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Monoblock is the horizontal arm of the L connection plate inside the block. It is a monoblock with the vertical plate (44) of the flat block with the L connection plate. There is a 90° angle between them. There are aerated concrete mortar passage holes (45) of the wide L connection plate on which the aerated concrete mortar will pass. It is an aerated concrete element shape that I have patented with my patent number. Therefore, I mentioned it here not to patent it, but to facilitate explanation and increase understanding. Monoblock It is the vertical arm of the L connection plate outside the block. It is a monoblock with the horizontal plate (43) of the flat block with L connection plate. There is a 90° angle between them. It runs vertically upwards on the inner surface of the production mold (1). Its outer surface is aligned with the rear outer surface of the flat block with L connection plate (42). There are screw holes (59) on the part of the block that passes above the upper level, through which the screws that will fix it to the column will pass. It is fixed by screwing the end of the vertical arm of the L connection plate, located on the upper edge of the production mold, to the plate-shaped elevation (58) to which it is screwed on the upper edge of the production mold. The aerated concrete mortar passage holes on the horizontal arm of the L connection plate are the holes on the horizontal arm of the connection plate. Therefore, it is not intended to obtain a patent, but for the purpose of explanation. I mentioned it here to make it easier and to increase the understanding. These are the wide holes on the horizontal plate (43) of the flat block with L connection plate, through which the aerated concrete mortar can pass. Their number varies according to the length of the block. The lower half of the lower row of the L connection plate system (46) (Figure 19 A, Figure 21): I have patented it with my patent number TR 2021 00599 B. Therefore, I mentioned it here not to patent it, but to facilitate the explanation and to increase the understanding. It forms the lower half of the lower row of the L connection plate system (46). It is a flat area. The bed (47) (Figure 19 A and B) where the vertical arm of the L connection plate extends in the upper half of the lower row and the upper half of the middle rows: L It is located in the upper half of the bottom row of the connection plate system (48) and in the upper half of the middle rows of the L connection plate system (51). It is a small, rectangular prism-shaped recess extending from the midline to the upper edge. The initial part of the vertical arm (44) of the L connection plate extends in this recess. The upper half of the bottom row of the L connection plate system (48) (Figure 19 A, Figure 21): It forms the upper half of the bottom row of the L connection plate system (48). At the lower edge of this upper half, in the middle, there is a gap called the horizontal arm entry gap (50) of the middle rows of the rectangular L connection plate system, through which the horizontal arm (43) of the L connection plate will enter the production mold (1). The upper part of this gap On the side, there is a groove called the bearing (47) of the vertical arm of the L connection plate in the shape of a rectangular prism, which extends to the upper edge of the block and in which the vertical arm of the L connection plate (44) will fit, extending in the upper half of the lower row and in the upper half of the middle rows. Lower half of the middle rows of the L connection plate system (49) (Figure 19 B, Figure 22): In the lower half of this block, there is a groove called the bearing (53) of the vertical arm of the L connection plate, which starts from the lower edge and continues up to half the height of the lower half, extending in the lower half of the upper row and in the lower half of the middle rows, in which the vertical arm of the L connection plate (44) will fit. The L connection plate system The horizontal arm entry range (50) of the middle rows and the bottom row (Figure 19 A and B): In the upper half of the bottom row (48) of the L connection plate system and in the upper half of the middle rows (51), it is the area located in the middle line and where the horizontal arm (43) of the L connection plate enters the production mold (1). The upper half of the middle rows of the L connection plate system (51) (Figure 19 B, Figure 22): It is the block placed in the middle rows of the wall and adjacent to the column. In this and also in the upper halves of the bottom row, the horizontal arm entry range (50) of the middle and bottom rows of the L connection plate system and in the upper half of the bottom row and in the upper half of the middle rows, where the vertical arm of the L connection plate extends The upper row (52) of the L connection plate system (Figure 19 C, 20 A and C): The height of this block is the height of a flat block. Starting from the middle of the lower edge and extending upwards by the height of block 1A, there is a rectangular prism-shaped groove called the bearing (53) of the vertical arm of the L connection plate, which extends in the lower half of the upper row of the L connection plate system and in the lower half of the middle rows. In the lower rows, this bearing is formed by the bearing-forming metallic extension plate (5 7) of the spacer apparatus. In the middle rows, this bearing is formed by the removable metal plate (64) which will form the bearing of the vertical extension of the L connection plate in the middle rows of the L connection plate systems. The bearing of the vertical arm of the L-connection plate extending in the lower half and the lower half of the middle rows (Figure 19 B and C): The vertical plate (44) of the flat block with L-connection plate extends into this bearing. This bearing is located both in the lower half of the upper row and in the lower half of the middle rows. In the lower rows, this bearing is formed by the bearing-forming metallic extension plate (5 7) of the spacer device. In the middle rows, this bearing is formed by the removable metal plate (64) which will form the bearing of the vertical extension of the L-connection plate in the middle rows of the L-connection plate systems. The entry gap (54) of the forming apparatus for the bearing of the vertical arm of the L-connection plate extending in the lower half of the upper row of the L-connection plate system (Figure 20 C): The bearing-forming apparatus It is the gap where the metallic extension plate (57) of the bed forming apparatus enters the production mould (1). Normally, the height of this gap is equal to the thickness of the metal plate. However, on the right and left side faces of multi-layer production moulds (1), the height of this gap is twice the normal. Top view of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system inside the production block of the bed forming apparatus (55) (Figure 20 A): The bed is 1% of the height of the block. Stopper of the bed forming apparatus (56) (Figure 20 B): It is the metallic part which is wider than the bed forming plate so that the metallic extension plate (57) of the bed forming apparatus does not get buried in the production mould (1). Metallic extension plate (57) (Figure 20 A and B): It is a flat, metallic plate that is located in the middle of the stopper (56) of the bed forming apparatus, on its inner surface facing the mould. Normally, the thickness of this plate is as much as the thickness of the metal plate. However, in multi-storey production moulds (1), this plate is twice as thick as the normal. Plate-shaped elevation to which the end of the vertical arm of the L connection plate is screwed on the upper edge of the production mould (58) (Figure 21 and 22): During the pouring of aerated concrete mortar into the production mould (1), in order to keep the L connection plate stable, the screws passing through these screw holes are screwed into the screw holes (59) on the vertical arm of the L connection plate (44) to which the vertical arm of the L connection plate will be screwed to the column. Screw holes (59) (Figure 21, 22): These are the holes on the free end of the vertical arm (44) of the L connection plate, which is outside the production mould (1). Their number can vary. The screws passing through these holes are immobilized by passing to the plate-shaped elevation (58) to which the end of the vertical arm of the L connection plate, rising from the upper edge of the production mould, is screwed on the upper edge of the production mould. Removable mould (60) (Figure 23): It is a hollow removable mould placed on the inside of the production mould (1), in the positive direction of the OX axis, on the length part. It reduces the width of the production mould (1). This reduces the width of the production mould, If there is no stretching or deformation problem during the pouring of aerated concrete mortar in the removable mold (60), it is placed on one side. If such a problem occurs, it can be placed on both sides. In this case, the width of this mold is divided in half. These problems can also be solved by applying this mold in several pieces along the length of the production mold (1). This multi-piece structure also allows these molds to be removed more easily. The same production mold (1) can be used in the casting of different aerated concrete elements. In addition, if there is not enough space left on the side of the standard production mold (1) to create an aerated concrete element mold, these remaining gaps can be filled with such void-filling removable molds. The heights are determined by the mortar being poured into the mold during the pouring of the aerated concrete mortar. It is slightly higher than the production mold to prevent it from filling. It is rigid enough not to stretch during the pouring of the aerated concrete mortar. For this purpose, it can be produced by placing rigid metal bars in a + or X shape from wall to wall at various heights of the interior walls, so as not to hinder the screwing operations. There are screw holes on their bases through which the screws that will fix them to the base of the production mold (1) will pass, so that they do not move during the pouring of the aerated concrete mortar. The positions of these screw holes are compatible with the screw holes (12) on the base of the production mold with screw holes on the screw hole base of the production mold below them or with the screw holes (68) on the additional metal plate (66) placed on the base of the production mold; they are aligned and matched. On top of them, a rigid metal bar cage (7) is placed to fix the removable molds. They are placed. There are screw holes on their upper parts. Removable molds containing screw holes in areas compatible with these holes are connected with a rigid metal bar cage (7) that stabilizes them. There are holding bars near the upper parts to facilitate removal from the production mold. Removal is done by hand or by holding these parts with machines. 10 They have open tops. Molds that create a gap on top may also have a removable cover (71). In this case, there are screw holes (8) on the upper surfaces of the covers, in the middle of their upper edges, except for the edges adjacent to the production mold (1). These holes are connected to the rigid metal bar cage (7) that fixes the removable molds, which contain screw holes in the areas compatible with these holes. It is very useful. Inner-upper edge of the removable mold (61) (Figure 23), which reduces the width of the production mold: If the production mold (1) is to be used in the production of flat blocks with L-connection plates (42) and a removable mold (60) is to be added to reduce the width of the production mold, plate-shaped elevations (5-8) are added to this edge, to which the end of the vertical arm of the L-connection plate is screwed to the upper edge of the production mold. They are open at the top. The cavity-forming molds may also have a removable cover (71) on top. In this case, there are screw holes (8) in the middle of the upper edges of the covers, excluding the edges adjacent to the production mold (1). These holes are connected to the rigid metal bar cage (7) that secures the removable molds, which contain screw holes in areas compatible with these holes. Removable mold (62) for shortening the length of the production mold (Figure 23): This is a hollow removable mold placed inside the production mold (1) in the positive direction of the OY axis. It shortens the length of the production mold (1). This removable mold (62), which shortens the length of the production mold, is placed on one side if no stretching or deformation occurs during the pouring of the aerated concrete mortar. If such a problem occurs, it can be placed on both sides. In this case, the width is divided in half. This allows the same production mold (1) to be used for the pouring of different aerated concrete elements. Furthermore, if there is insufficient space on the bottom side of the standard production mold (1) to create an aerated concrete element mold, these remaining gaps can be filled with these types of removable void-filling molds. Their height is slightly higher than the production mold to prevent the aerated concrete mortar from filling the mold during pouring. They are rigid enough to prevent stretching during the pouring of the aerated concrete mortar. To achieve this, rigid metal bars can be placed in a + or X pattern across the interior walls at various heights, without hindering screwing operations. These problems can also be overcome by applying several pieces of this mold along its length. This structure also allows for easier removal of these molds. Their bases have screw holes for the screws that will secure them to the base of the production mold (1) to prevent displacement during the pouring of the aerated concrete mortar. The positions of these screw holes are aligned and matched with the screw holes (12) on the base of the production mold with screw holes on the base of the production mold with screw holes on the base of the production mold below them, or with the screw holes (68) on the additional metal plate (66) placed on the base of the production mold. A rigid metal bar cage (7) is placed on top of the removable molds, securing them. There are screw holes on the upper sections. These holes are connected to the rigid metal bar cage (7), which contains screw holes in areas compatible with these holes. They are open on top. Molds that create a gap on top may also have a removable cover (71). In this case, there are screw holes (8) on the upper surfaces of the covers, in the middle of their upper edges, except for the edges adjacent to the production mold (1). These holes are connected to the rigid metal bar cage (7), which contains screw holes in areas compatible with these holes. There are holding bars near the upper sections to facilitate removal from the production mold. Removal is done by hand or by machine, by holding these parts. It is very useful. In the upper row of L-shaped systems, the screw holes (63) of the bearing forming apparatus that will form the bearing of the vertical extension of the L-shaped plate (Figure 20 B): The screws passing through these screw holes fix the stopper (56) of the bearing forming apparatus to the outer surface of the wall of the production mold (1). In the middle row of L-shaped systems, the removable metal plate (64) that will form the bearing of the vertical extension of the L-shaped plate (Figure 22): In these molds, metal plates, not hollow molds, are used to ensure rigidity. These metal plates are immobilized by screwing them to the lower area of the side wall of the production mold (1) through the screw holes (65) of the removable metal plate that will form the bearing of the vertical extension of the L connection plate in the middle rows of the systems with L connection plates (Figure 22): These are the screw holes through which the screws that will fix them to the lower area of the side wall of the production mold (1) will pass, which are located on the removable metal plates (64) that will form the bearing of the vertical extension of the L connection plate in the middle rows of the systems with L connection plates. Additional metallic plate (66) placed on the base of the production mold (Figure 24): Thanks to this removable part, the same production mold (1) can also be used in the production of different aerated concrete elements. All of the formations on it are identical to the base surface of the fixed-base production mold (1) to be used in the production of the same aerated concrete element. It is very versatile. Areas on the additional metallic plate to which the removable molds will be fixed (67) (Figure 24): These areas are identical to the base surface of the fixed-base production mold (1) to be used in the production of the same aerated concrete element. Screw holes on the additional metallic plate (68) (Figure 24): The locations of these screw holes are the same as the locations and numbers of screw holes on the base surface of the fixed-base production mold (1) to be used in the production of the same aerated concrete element. Removable cavity-forming mold with quarter-ellipse curvature at the ends (69) (Figure 13): It is formed by rounding one side of the front and back ends of a rectangle to a quarter-ellipse shape. The cavity-forming mold is a prismatic structure. It is used in the production mold (1) with a wide-top block (30) for the upper row of the half-wall to complete the shape of the virtual aerated concrete element's upper surface into a quadrangle. The tops are open. Rigid metallic plates with screw holes (4) on the upper edges of the removable cavity-forming molds are used to connect the mold to the metal bar cage for immobilization. The removable cavity-forming molds may also have a removable cover (71) on top. In this case, the upper surfaces of the covers, excluding the edges adjacent to the production mold (1), have screw holes (8) in the center of their upper edges. These holes are connected to the removable molds, which contain screw holes in areas compatible with these holes, with a rigid metal bar cage (7) that stabilizes them. It is very useful. Removable mold with semi-elliptical curvature at the ends (70) (Figure 13): It is formed by rounding the two sides of the front and rear ends of a rectangle into a semi-elliptical shape. The space generator is a prismatic structure. In the production mold (1), which has a wide top for the upper row of half walls, the virtual aerated concrete element is used to complete the upper surface shape into a quadrilateral. It has open tops. The upper edges of the removable cavity molds have rigid metallic plates with screw holes (4) on them to ensure immobilization and to connect them to the metal bar cage. The cavity molds can also have a removable cover (71) on top. In this case, the covers have screw holes (8) on their upper surfaces, in the center of their upper edges, except for the edges adjacent to the production mold (1). These holes are used to connect the removable molds with the rigid metal bar cage (7) that secures them in areas compatible with these holes. It is very useful. Removable cover of the cavity molds (71) (Figure 5 B): The cavity molds can also have a removable cover. The edges of the lid extend slightly downward from the upper edges of the mold. These holes contain screw holes. The side edges of the blanking molds can be screwed into them or simply fitted tightly. The upper surfaces of the lids have screw holes (8). These holes connect the removable molds, which are located in areas aligned with these holes, to a rigid metal bar cage (7) that secures them. The removable blanking mold (72) (Figure 21) reduces the depth of the production mold. It is a hollow, rigid, removable blanking mold, shaped like a rectangular prism. It is placed between the upper surface of the base of the production mold (1) and the additional metallic plate (66) placed on the base of the production mold. It can be a single piece or a two- or four-piece assembly. It reduces the depth of the production mold (1). It enables the plant's standard production mold (1) to be used as a single-layer production mold. The bottom row of the L-connection plate system (73) (Figure 19 A, 21): It consists of a monoblock connection of two sections named the lower half of the bottom row of the L-connection plate system (46) and the upper half of the middle rows of the L-connection plate system (51). I used this binary nomenclature to simplify the explanation. The middle rows of the L-connection plate system (74) (Figure 19 B, 22): It consists of a monoblock connection of two sections named the lower half of the middle rows of the L-connection plate system (49) and the upper half of the middle rows of the L-connection plate system (51). I used this binary nomenclature to simplify the explanation. Preparation of Production Molds for Industrial Application (I) To avoid unnecessary drawings in technical drawings, I often drew two aerated concrete elements, one in the positive OX axis and the other in the positive OY axis. The aerated concrete element blocks in these technical drawings, except for single-story production molds, can be duplicated in the positive OX axis and the other in the positive OY axis using the "mirror" command in technical drawing programs. Production mold (1) can be enlarged according to the new drawing, and the number of blocks to be produced can be increased. 1. Selecting the base of production mold (1): Application of the screw-hole base (10) (Figure 3) of the production mold: This mold is used in the production of a single type of aerated concrete element. Application of the additional metallic plate (66) (Figure 24) placed on the base of the production mold: By changing the additional metallic plate, production mold (1) can be used to produce different types of aerated concrete elements. This part is separate for each type of aerated concrete element. For the production of each different aerated concrete element, an additional metallic plate (66) is placed on the base of a different screw-hole production mold. If a removable mold (72) is used to reduce the depth of the production mold, it is placed on it. Application of the removable mold (72) to reduce the depth of the production mold (Figure 24): If a standard production mold is used for single-story production, a removable mold (72) to reduce the depth of the production mold is placed on the base of the production mold (1). On top of this, if used, an additional metallic plate (66) is placed on the base of the production mold / a removable mold (60) to reduce the width of the production mold / a removable mold (62) to reduce the length of the production mold. If these are not used, the removable mold (2) is used. 2. Removable mold (2) (Figure 1) application: The molds for the aerated concrete elements within the production mold (1) are created by placing the removable molds (2) to create the space in appropriate locations within the production mold (1). A mold in the original shape of the aerated concrete element is never placed within the production mold. The removable spacer molds (2) are placed on the screw-hole base (10) of the production mold or on the additional metallic plate (66) placed on the base of the production mold placed on this base, on the areas (67) to which the removable spacer molds will be fixed. The screws are fixed by passing through the screw holes (12) on the screw holes (68) on the screw holes (68) on the screw-hole base of the production mold or by connecting them to the additional metallic plate (66) placed on the screw-hole base (10) of the production mold or on the base of the production mold placed on this base. The height of the removable spacer molds (2) is longer than the height of the production mold (1) to prevent the entry of aerated concrete mortar into them. In cases where rigidity cannot be achieved in the common voids of two or four aerated concrete elements, each block can be positioned separately, thereby reducing the size of the void-forming molds. In these cases, the upper unit boundaries of the aerated concrete element and the void-forming molds must always be square or rectangular during positioning. Such a design is illustrated in Figure 7, Island, Common Void. In Figure 7 B, considering that rigidity cannot be achieved in a common space, the space of each aerated concrete element has been designed separately, but the rule of creating a square or rectangular shape has not been deviated from. The outer boundaries of these small space-forming molds and the total structure of the aerated concrete element have been positioned in a rectangular shape in accordance with this rule, in accordance with the linear cuts to be made in the positive direction of the OX axis and the positive direction of the OY axis. As in Figure 7 B, additional rigidity is obtained by leaning one wall of the removable space-forming molds (2) against the side wall of the production mold (1). We see the same situation in Figure 10 A and B. The two common void-forming areas of the four aerated concrete elements in A are considered as four parts (areas) for each aerated concrete element separately in order to ensure rigidity, and are designed in a rectangular shape in accordance with the linear cuts in the positive direction of the OX axis and the positive direction of the OY axis. If the removable cover (71) of the void-forming molds is to be placed on them, the cover is closed. Application of removable mold (60) to reduce the width of the production mold and removable mold (62) to reduce the length of the production mold (Figure 23) If the plant wants to produce a small number of aerated concrete elements in a series in the positive direction of the OY axis or if there is a gap less than the width of an aerated concrete element in the production mold (1), it can practically reduce the standard production molds (1) by placing a removable mold (60) to reduce the width of the production mold along the positive direction of the OX axis. The same application can be shortened by placing a removable mold (62) to reduce the length of the production mold along the positive direction of the OY axis. The height of these molds is also longer than the height of the production mold (1) to prevent aerated concrete mortar from entering them. If the removable cover (71) of the cavity forming molds is to be placed on them, the cover is closed. Application of the rigid metal bar cage (7) (Figure 2) securing the removable molds: The rigid metal bar cage (7), which is compatible with the upper edges of the removable cavity forming molds (2), is placed on the removable cavity forming molds (2). If the removable cavity forming molds have removable covers (71), the cage is placed on the cover. The bars are connected to the removable moulds (2) and, if any, to the removable mould (60) which reduces the width of the production mould and to the removable mould (62) which shortens the length of the production mould, by screws passed through the screw holes on the rigid metallic plates (8) with screw holes on the rigid metal bars and the rigid metallic plate (9) with screw holes on the removable mould (9) which creates the vertical beam gap. In cases where the removable space forming mould (28) placed in the corner areas of the flat block production moulds with rounded ends for half walls, the removable space forming mould (29) between two flat blocks with rounded ends for half walls, the removable space forming mould with quarter ellipse curvature at the ends (69) and the removable space forming mould with half ellipse curvature at the ends (70) are used, rigid metal bar cages (7) that are compatible with the upper edges of the above-mentioned space forming structures are used. Pouring the aerated concrete mortar into the production mould (1): The aerated concrete mortar is poured into the symmetrical spaces that will form the aerated concrete element to be produced, from the metal bar cage intervals, with a pipe end. Because the aerated concrete element cavities are symmetrical, the mortar dispensing machine fills the production mold with mortar without stopping completely, simply pausing and restarting the dispensing process. This is not necessary when filling the production molds of many aerated concrete elements; mortar can be filled quickly from a single location or by moving the dispensing end. Disassembly of the mold: After the aerated concrete mortar hardens, if present, the apparatus (55) that forms the bearing of the vertical arm of the L-connection plate in the bottom and middle rows of the L-connection plate system is removed from the side walls of the production mold (1). Then, the cage is released and the cage is removed from the production block by unscrewing the screws of the removable molds (2) and, if any, the removable mold (60) and the removable mold (62) that reduce the width of the production mold under the rigid metal bar cage (7) that fixes the removable molds. The removable covers (71) of the removable molds, if any, are removed. The screws at the base of the removable molds (2) and, if any, the removable mold (60) and the removable mold (62) that reduce the length of the production mold are removed and these molds are removed. In the center, numerous aerated concrete elements, shaped and bonded together, stand side by side along the positive OY axis and the positive OX axis. Cutting begins: I've shown the block cutting lines in the technical drawings with thicker lines. Cutting is done along a linear line parallel to the positive OX axis and the positive OY axis, as in current aerated concrete cutting techniques. Separation into layers is done at intervals equal to the desired block height, along the negative Z axis from the right or left side, as is done in current production. Production molds (1) for some newly designed aerated concrete elements containing reinforcement are drawn for single-layer production; therefore, horizontal cutting is not performed on the side face. The technical drawing descriptions for these molds include the phrase "single-layer production mold (1)." There is no loss of aerated concrete in the cuts. Installation of the multi-layer production mould (1) and cutting technique of the production blocks for L-, T- and +-shaped connectors (Figures 1, 4 and 5): For L-shaped connectors (5), T-shaped connectors (13) and +-shaped connectors (14), the production moulds (1) are always prepared in such a way that the + shape is formed. The removable cavity formers (2) are placed inside the production mould (1) in this direction. The production mould (1) of the +-shaped connector (14) is formed by the removable cavity formers (2) and the inner surface of the walls of the production mould (1). The width of all arms of the + shaped connector (14) is adjusted to twice the width of the flat block used in the area by positioning the removable molds (2) and if these arms are divided into four by cutting them lengthwise in the middle, 4 L shaped connectors (5) are formed (Figure 1). If the width of the arms of the 0 + shaped connector (14) in the positive direction of the OY axis is adjusted to be twice the width of the flat block used in the region and the arms in the positive direction of the OX axis are adjusted to be the same as the width of the arms of the flat block used in the region by positioning the removable molds (2) and the arms in the positive direction of the OY axis are divided into two by cutting them in the middle longitudinally, 2 T shaped connectors (13) will appear (Figure 4). If the width of the arms of the 0-shaped connector (14) is made the same as the width of the flat block used in the area by positioning the removable molds (2) and cutting is made from the ends of these arms, one + shaped connector (14) will be created (Figure 5). If the mirror command is applied as in Figure 1, four + shaped connectors will be created. 2. Preparation of the stepped flat block (15), multi-layer production mold (1), and the cutting lines of the production block (Figure 6): In the picture, we see the production mold (1) of the 10-step flat block (15). This mold can be enlarged in the positive OX axis and the positive OY axis using the "mirror" command. The shape of the production mold (1) is created using removable molds (2) and the inner surfaces of the walls of the production mold (1). Cuts parallel to the positive OY axis are made from the bottom edges of the blocks, i.e., along the mirror command application lines. Cuts parallel to the positive OX axis are made from the junction line of the front and back faces of the blocks, i.e., along the mirror command application lines. Cuts parallel to the desired height of the blocks are made from the side faces, along the negative Z axis direction, parallel to the top face of the main block, thus dividing the block into layers. 12. Preparation of the reinforced lintel (18), multi-layer production mold (1), and the cutting lines of the production block (Figure 7 A and B): Figure 7 shows the production mold (1) for four reinforced lintels (18). This mold was created by multiplying an unreinforced lintel in the positive OX axis and the positive OY axis using the "mirror" command. The number can be further increased using the same method. The shape of the production mold (1) is created by the removable molds (2) that create the space and the inner surface of the walls of the production mold (1). The common space-forming removable molds (2) in the middle of both blocks can be divided into two to increase rigidity, as seen in Figure 7 B. The cutting is done from the lower edges of the arms of the lintel (19) and the connection lines between the arms of the lintel (19), that is, from the application lines of the mirror command. 13. Reinforced lintel (22), preparation of the single-layer production mold (1) and the cutting lines of the production block (Figure 8): In the picture, we see the production mold (1) of 4 reinforced lintels (22). This mold can be enlarged in the positive direction of the OX axis and the positive direction of the OY axis with the "mirror" command, the number of blocks can be increased. The shape of the production mold (1), the space-forming removable molds (2) and the production mold (1) is formed by the inner surface of the walls. The screws (20) will come from the rigid metal plates (8) with screw holes on the rigid metal bars, which will be inserted into the holes (21) to fix the reinforcement located in the area near the arm ends and in the middle of the body length. The screws will keep the block parallel to the ground and in the middle of the height of the block. The removable mold (72) may be required to reduce the depth of the production mold. The cutting lines are made from the joint line of the ends of the lintel arms (19) of the adjacent blocks in the positive direction of the OY axis and from the joint lines between the lintel arms (19) of the two adjacent blocks in the positive direction of the OX axis, that is, from the application lines of the mirror command. 14. Single-walled flat block with foam filling area (23), preparation and production of the multi-layer production mold (1) Cutting lines of the block (Figure 9): The figure shows a single-walled flat block (23) with 8 foam-filled areas, increased in number in the positive OX axis direction and the positive OY axis direction with the "mirror" command. The shape of the production mold (1) is created by the removable molds (2) that create the gaps and the inner surface of the walls of the production mold (1). The cutting lines parallel to the positive OY axis of the production block pass through the end connection lines of the single walls of the adjacent blocks in the positive OY axis direction and the top and bottom surface connections of the bodies. The cutting line parallel to the positive OX axis passes through the end surface connections of the body lengths of adjacent blocks in the positive X axis direction, i.e., the application lines of the mirror command. . Flat block (25) with foam-filled areas and double walls, multi-layer production mold (1) Preparation and cutting lines of the production block (Figure 10 A and B): Figure 10 shows a double-walled flat block (25) with 4 foam-filled areas, multiplied in number in the positive direction of the OX axis and the positive direction of the OY axis, using the "mirror" command. The foam-filled areas of the two adjacent blocks, positioned above and below, in the positive direction of the OX axis, are created with removable molds (2). The cutting lines of the production block are the same as those of the single-walled flat block (23) with foam-filled areas. In Figure 10 B, assuming that the common removable molds (2) in Figure 10 A cannot provide sufficient rigidity, these two molds are divided into four by a partition made parallel to the positive direction of the OY axis. The upper two blocks are rotated 180° along the positive direction of the OY axis. Additional rigidity is achieved by making one face of the removable spacer molds (2) against the inner surface of the front wall of the production mold (1). The same advantage can be achieved by rotating the removable spacer molds (2) in the positive direction of the OY axis by 180° in the positive direction of the OY axis in two molds of the same shape. However, when the number of rows in the positive direction of the X axis is increased, this will not be beneficial. If it is done in the last row, it will be beneficial. 16. Horizontal beam forming U block (26), preparation of the multi-layer production mold (1) and cutting lines of the production block (Figure 11): The shape of this production mold (1) is formed by the removable spacer molds (2) and the inner surface of the walls of the production mold (1). Figure 11 shows, There are four horizontal beam forming U blocks (26). The unit shape is multiplied in the positive direction of the OX axis and the positive direction of the OY axis using the "mirror" command to obtain the production pattern in Figure 11. With the same command, the number of pieces in each layer can be multiplied numerically in the positive direction of the OX axis and the positive direction of the OY axis. The cutting line parallel to the positive direction of the OX axis passes through the facing faces of the arms of the two blocks copied in the positive direction of the OY axis using the mirror command, positioned side by side, that is, the line to which the mirror command is applied. The cutting line parallel to the positive direction of the OY axis is from the ends of the arms of two blocks copied in the positive direction of the OX axis with the mirror command. 17. The flat block with rounded ends for the half-wall (2 7), preparation of the multi-layer production mold (1) and the cutting lines of the production block (Figure 12): The top view of the aerated concrete element is rectangular with rounded ends facing the side walls of the production mold (1). The faces of two adjacent aerated concrete elements facing each other in the positive direction of the OY axis are flat. The removable mold (28) that creates the space is placed in the inner corner areas of the production mold (1) and the corner areas of the production molds. For two half-walls that are adjacent to each other in the positive direction of the OX axis, the rounded-end flat block (27) is shaped by placing the removable mould (29) in the space between the ends of the rounded-end flat block (27) and the inner surface of the production mould (1) and forming the eight half-walls. The production mold (1) in Figure 12 is obtained by duplicating a block in the positive direction of the OY axis and the positive direction of the OX axis with the mirror command. With the mirror command, the number of blocks can be increased in the positive direction of the OX axis and the positive direction of the OY axis. Cuts are made on the lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis, where the mirror command is applied. Cuts for dividing into layers are made from the side face in the negative direction of the Z axis according to the height of the block to be produced. 18. Preparation of the multi-layer production mold (1) with a wide top side for the top row of the half wall (30) and the cutting lines of the production block (Figure 13): The picture shows 4 blocks duplicated with the mirror command in the positive direction of the X axis and the positive direction of the Y axis. With the same command, the production mold (1) is in the positive direction and in the positive direction of the Y axis, it can be enlarged, and the number of blocks can be increased. The cutting lines of the production block pass through the lines to which the mirror command is applied, in the positive direction of the X axis and in the positive direction of the Y axis. Blocks are formed by making cuts at intervals equal to the height of the masonry element from the side face of the production block, along the negative direction of the Z axis, with the shapes of the aerated concrete elements, the removable molds with quarter-ellipse curved ends (69), the removable molds with half-ellipse curved ends (70) and the inner surfaces of the walls of the production mold (1). 19. The flat block with double-sided skirting (31), the preparation of the multi-storey production mold (1) and the cutting lines of the production block (Figure 14): The picture shows 4 blocks duplicated with the mirror command, in the positive direction of the OX axis and the positive direction of the OY axis. The shape of the block is created by the removable molds (2) that create the space and the inner surface of the walls of the production mold (1). The number of blocks can be increased with the mirror command. The cutting lines of the production block pass along the positive OX axis and the positive OY axis, along the lines where the mirror command is applied. In other words, parallel to the positive OX axis, it passes between the facing faces of the skirting board arms. Parallel to the positive OY axis, it passes through the upper edge of the flat blocks (31) with skirting boards on both sides. The flat block (33) with a single-sided skirting board, preparation of the multi-layer production mold (1) and the cutting lines of the production block (Figure 15): The figure shows four aerated concrete element shapes duplicated with the mirror command, along the positive OX axis and the positive OY axis. In the middle of these, a common rectangle is formed, the longest axis of which extends along the positive OX axis. We see a shaped removable mold (2) that creates a gap. The shape of the aerated concrete elements is created by the removable molds (2) and the inner surface of the walls of the production mold (1). The number of blocks can be increased with the Mirror command. The cutting line parallel to the positive OX axis of the production block passes between the facing faces of the skirting boards of two blocks to which the Mirror command was applied in the positive OY axis direction. The cutting line in the positive OY axis of the production block passes between the top surfaces of two adjacent front-back blocks copied with the Mirror command in the positive X axis direction. In other words, in the positive OX axis direction, it passes between the facing faces of the skirting boards. The internal stepped arm connection (35) for the double wall panel, the preparation of the multi-layer production mold (1) and the cutting lines of the production block (Figure 16): In the picture above, OY In the positive direction of the axis, we see the block (35) for the internal stepped arm connection for two pairs of wall panels, duplicated with the mirror command. The shape of the block is created by the removable molds (2) that create the space and the inner surface of the walls of the production mold (1). The cutting line parallel to the positive direction of the OX axis is the line to which the mirror command is applied in the positive direction of the OY axis. The cutting line between the inner stepped block (35) for two adjacent double wall panels and the two adjacent non-stepped blocks below in the positive direction of the OY axis is the connection surface parallel to the positive direction of the OY axis between the two adjacent blocks at the front and the two adjacent blocks at the back. To avoid multiplying the number of figures, I have shown two different examples in the same figure. The non-stepped block connection (36) for the double wall panel, the preparation of the multi-layer production mold (1), and the cutting lines of the production block (Figure 16): The figure below shows the aerated concrete element shape for the non-stepped block connection (36) for two adjacent double wall panels, duplicated with the mirror command in the positive direction of the OY axis. At the center of the aerated concrete elements is a common rectangular removable mold (2) with a long axis parallel to the positive OY axis. The shape of the blocks is created by the removable molds (2) and the inner surfaces of the walls of the production mold (1). The cut line in the positive OX axis direction is the line parallel to the positive Y axis direction, where the mirror command is applied. In other words, it is the joint surface formed by the arms of adjacent blocks at the midline. The cut line between the upper inner stepped blocks, parallel to the positive OY axis direction, is the joint surface parallel to the positive OY axis between the two adjacent blocks at the front and the two adjacent blocks at the back. To avoid multiplying the number of figures, I have shown two different examples in the same image. Preparation of the multi-layer production mold (1) with an internal stepped beam connection for a double wall panel (38) and the cutting lines of the production block (Figure 17): The figure shows two blocks (38) with an internal stepped beam connection for a double wall panel, side by side, in the positive Y-axis direction, duplicated with the mirror command. The shape of the block is created by the removable molds (2) that create the gap and the inner surface of the walls of the production mold (1). The cutting line in the positive X-axis direction passes between the contacting arms of the two blocks. The cutting line between the lower, non-stepped blocks is the horizontal connection surface between the two adjacent blocks at the front (the side closest to the positive OY-axis direction) and the back (the side farthest from the positive OY-axis direction) and the two adjacent blocks at the back (the side farthest from the positive OY-axis direction). To avoid multiplying the number of shapes, I have shown two different examples in the same figure. 24. Preparation of the multi-layer production mold (1) for a stepless beam connection for a double wall panel (39) and the cutting lines of the production block (Figure 17): The figure shows two blocks for a stepless beam connection for a double wall panel (39), side by side on the side away from the positive OY axis, in the positive X axis direction, duplicated with the mirror command. The shape of the block is created by the removable molds (2) that create the gaps and the inner surface of the walls of the production mold (1). The cutting line parallel to the positive OX axis is the connection line between the blocks. The inner stepped blocks on the side closest to the positive OY axis and the cutting line between them are the joint surfaces between two adjacent blocks at the front (the side closest to the positive OY axis) and two adjacent blocks at the back (the side farthest from the positive OY axis). To avoid multiplying the number of figures, I have shown two different examples in the same figure. Preparation of the multi-layer production mold (1) for the inner stepped base connection (40) for the double wall panel and the cutting lines of the production block (Figure 18): In the figure, there are two inner stepped base connection blocks (40) for the double wall panel at the front, side by side, in the positive OY axis direction, duplicated with the mirror command. The shape of the block is created by the removable cavities (2) and the inner surface of the walls of the production mold (1). The cutting line parallel to the positive direction of the OX axis passes through the joint line formed by the arms of the blocks. The cutting line between the stepless blocks on the side farthest from the positive direction of the OY axis and the joint surface parallel to the positive direction of the OY axis is the joint surface between the two adjacent blocks on the front side and the two adjacent blocks on the back side, parallel to the positive direction of the OY axis. To avoid multiplying the number of figures, I have shown two different examples in the same figure. 26. Preparation of the stepless base connection (41) for the double wall panel multi-layer production mold (1) and the cutting lines of the production block (Figure 18): In the figure, at the back (farthest from the positive direction of the OY axis), there are two stepless base connection blocks (41) for the double wall panels, side by side, in the positive direction of the OY axis, duplicated with the mirror command. The shape of the block is created by the removable molds (2) that create the space and the inner surface of the walls of the production mold (1). The cutting line, parallel to the positive direction of the OX axis, is the joint line formed by the arms of the two blocks. The cutting line, parallel to the positive direction of the Y axis, between the inner stepped blocks at the front (farthest from the positive direction of the OY axis) and the joint surface, parallel to the positive direction of the OY axis, between the two adjacent blocks at the front and the two adjacent blocks at the back. To avoid multiplying the number of shapes, I have shown two different examples in the same picture. 27. Preparation of the production molds (1) of L-connection plate systems and cutting lines of the production block (Figures 19 A, B, C, D, 20 A, B, C, 21 and 22): The L-connection plate system consists of three different blocks, to be applied to the bottom row adjacent to the column, the middle rows, and the top row. Accordingly, three different production molds (1) are used. 0 The bottom row of the L-connection plate system (73) (Figure 19 A, Figure 21): It is a single-story production mold (1). The bottom row consists of the monoblock combination of the bottom half of the bottom row of the L-connection plate system (46) and the top half of the bottom row of the L-connection plate system (48). It contains two adjacent blocks in the positive direction of the OY axis and the desired number of blocks in the positive direction of the OX axis. The vertical arm (44) of the L-connection plate of the two blocks in the positive direction of the OY axis is located on the right and left inner faces of the production mold. Therefore, on the upper edges of the side walls of the production mold (1), there is a plate-shaped elevation (58) to which the end of the vertical arm of the L-connection plate, one for each aerated concrete element block, is screwed onto the upper edge of the production mold. The vertical arm (44) of the L-connection plate is connected to these elevations via screw holes (59) to which the vertical arm of the L-connection plate is screwed. This immobilization of the vertical arm (44) of the L-connection plate during the pouring of the aerated concrete mortar is ensured. After these screws are loosened after pouring, the side walls of the production block (1) are loosened. In the resulting block, only on the top surface, along the lines where the mirror command is applied, a linear cut is made from the midline of the positive OY axis, parallel to the positive OX axis, along the long axis of the production mold (1). Linear cuts are made transversely to the production mold (1) from the mirror lines parallel to the positive OY axis, and from the mirror lines between the aerated concrete elements. The application of a removable mold (72) to create a gap may be necessary to reduce the depth of the production mold. The top row (52) of the L-connector plate system (1) (Figure 19 C, Figure 20 A, B, and C): This is a multi-layer production mold (1). The production mold (1) is designed to produce two blocks side by side in each row, in the positive OY axis direction (Figures 19 C, 20 A, and C). In the positive direction of the OX axis, any number of blocks can be produced. To form the bearing (53) of the vertical extension of the L connection plate located in the lower half of the upper row and middle rows of the L connection plate system extending upward from the outer face of the lower edge of the block, the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system, located on the right and left side faces of the production mold (1) and adjacent to each other in the negative direction of the OZ axis, are arranged as a back-to-back monoblock. These gaps are one for the two blocks positioned top and bottom in the negative direction of the OZ axis. However, since the double bearing forming metallic extension plate (5 7) of the forming device will enter this area, the height of this gap is twice the thickness of the metal plate. The metallic extension plate (57) of the bearing forming apparatus is placed in the entry gaps (54) of the apparatus forming the bearing of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system and the apparatus is immobilized by screwing it through the screw holes (63) of the bearing forming apparatus which will form the bearing of the vertical extension of the L connection plate in the upper row in the L connection systems located on the stopper (56) of the bearing forming apparatus on the outer surfaces of the production mold (1). After the aerated concrete mortar is poured and hardened, the screws are unscrewed from the screw holes (63) of the bearing forming apparatus which will form the bearing of the vertical extension of the L connection plate in the upper row in the L connection systems. The apparatus is pulled out of the production mold (l). The side walls of the production mold (1) are removed. Linear cuts are made from the top, along the positive OY axis and the positive OX axis, along the lines where the mirror command is applied, as shown in Figures 20 A and C. Horizontal cuts are made from the side face, along the negative OZ axis, to the height of the masonry element block. Middle rows of the L-shaped connection plate system (74) (Figure 19 B, Figure 22): This is a single-story production mold (1). Production mold (1) is designed to create two adjacent blocks along the positive Y axis and as many blocks as desired along the positive X axis. A removable mold (72) may be required to create a gap to reduce the depth of the production mold. At the lower edge of the lower half, in the middle rows of L-connection plate systems, the removable metal plate (64), which will form the bearing of the vertical extension of the L-connection plate, is fixed to the inner surface of the production mold (1) by screwing it through the screw holes (65) of the removable metal plate, which will form the bearing of the vertical extension of the L-connection plate, in the middle rows of L-connection plate systems. Then, the vertical arm of the L-connection plate (44) is immobilized by screwing it to the plate-shaped elevation (58) to which the end of the vertical arm of the L-connection plate is screwed on the upper edge of the production mold, with screws passing through the screw holes (59) on which the vertical arm of the L-connection plate will be screwed to the column. Aerated concrete mortar is poured. After the mortar hardens, the screws passing through the screw holes (59) for the vertical arm of the L connection plate are removed. The front, rear, and side walls of the production mold are removed. Cutting begins. A linear cut is made along the entire block, parallel to the positive OX axis and along the center of the positive OY axis, along which the mirror command is applied. The block is then divided into two longitudinally symmetrical pieces. Then, linear cuts are made between the blocks adjacent to each other, along the OX axis, parallel to the positive OY axis, along the lines where the mirror command is applied.

Claims (1)

REQUESTS 1. These are production molds for linear, serial cutting of new design aerated concrete production blocks in the X-axis positive direction, Y-axis positive direction and Z-axis negative direction. Their features are; These production molds are L-shaped connector (5), T-shaped connector (13), +-shaped connector (14), stepped flat block (15), unreinforced lintel (18), reinforced lintel (22), single-walled flat block with foamed filling area (23), double-walled flat block with foamed filling area (25), horizontal beam forming U block (26), flat block with rounded ends for half wall (2-7), wide top block for half wall upper row (30), flat block with skirting on both sides (31), flat block with skirting on one side (33), internal stepped column connection for double wall panel (35), non-stepped column connection for double wall panel (36), internal stepped beam connection for double wall panel (38), non-stepped beam connection for double wall panel (39), internal stepped the production moulds (1) for the base connection (40), the stepless base connection for the double wall panel (41) and the flat blocks with L connection plates (42); the flat blocks with L connection plates (42) consist of three different block types named the upper row of the L connection plate system (52), the lower row of the L connection plate system (73) and the middle rows of the L connection plate system (74); the production mould (1) is in the shape of a rectangular prism; Within, according to the type and number of aerated concrete elements to be produced, different sizes and numbers of removable moulds (2) forming gaps, removable moulds (3) forming vertical beam gaps, flat block production moulds with rounded ends for half walls, removable moulds (28) forming gaps placed in corner areas, removable moulds (29) forming gaps between two flat blocks with rounded ends for half walls, removable metal plate (64) forming the bed of the vertical extension of the L connection plate in the middle rows of L connection plate systems, removable mould with quarter ellipse curved ends (69) and half ellipse curved ends there can be a removable mold (70); there can be a removable mold (60) on the inner surface of the edges of the production mold (1) to narrow the width of the production mold and a removable mold (62) to shorten the length of the production mold; there can be a removable mold (72) creating a gap to reduce the depth of the production mold on the inner-upper surface of the base of the production mold (1); except for the removable mold (72) creating a gap to reduce the depth of the production mold, the lengths of all molds creating a gap are longer than the production mold (1); there are rigid metal bars in the shape of X, + or parallel to each other inside all molds creating a gap; there are screw holes on their bases; they are inflexible and rigid; It is characterized by the presence of cuts called screw holes (4) on the upper parts of the removable molds that create a gap, except for the removable mold that creates a gap (72) that reduces the depth of the production mold; longitudinal and transverse block cutting lines (6) passing through the lines where the aerated concrete element blocks are multiplied with the mirror command in the positive direction of the OX axis and the positive direction of the OY axis. It is the production mold (1) mentioned in Request 1 and its feature is; it is empty inside; its top is open; it is in the shape of a rectangular prism; its walls are composed of rigid metal plates; its walls can be assembled and disassembled; the production molds (1) to be used to produce a single type of aerated concrete element are in the shape of the screw hole base (10) of the production mold; In production moulds where removable moulds with voids (2) will be used, there should be areas (11) on the base of the production mould with screw holes where the removable moulds with voids will be fixed and screw holes (12) on the base of the production mould with screw holes; in production moulds where voids are not used, there should be no screw holes (12) on the base of the production mould with screw holes; in production moulds of aerated concrete elements with L connection plate (1), there should be plate-shaped elevations (5 8) on the upper-inner edges of the walls forming the right and left side faces, to which the end of the vertical arm of the L connection plate is screwed on the upper edge of the production mould; It is characterized by the fact that the upper row (52) of the L connection plate system has the entry gaps (54) of the forming apparatus, which forms the bearing of the vertical arm of the L connection plate extending in the lower half of the upper row of the L connection plate system on the right and left side walls of the production mold (1); its base is formed by the screw-hole base (10) of the production mold or by the additional metallic plate (66) to be placed on the base of the production mold; on its inner sides, there can be a removable mold (60) that narrows the width of the production mold and a removable mold (62) that shortens the length of the production mold; on the inner-upper face of the base of the production mold (1), there can be a removable mold (72) that reduces the depth of the production mold. The removable cavity forming mould mentioned in request 1 is (2) and its features are; being empty inside; having a closed base and an open top or having a removable cover (71) on top of the cavity forming moulds; having square or rectangular upper sections; being in the shape of a rectangular prism or square prism; being made of rigid metal plates; two or four aerated concrete elements can have common cavities; these cavity forming moulds can be made individually, separately or as a pair of monoblocks; the length of these moulds is longer (higher) than the length of the production mould (1); being placed on the areas (11) where the cavity forming removable moulds will be fixed on the base of the production mould (1) with screw holes; It is characterized by having holding bars on its upper part; having screw holes on its base; having screw holes (4) on the upper part of the removable molds that create space in the middle parts of the edges that are not adjacent to the edges of the production mold (1); having these screw holes on the upper surface of the cover in the removable molds with removable covers (71); these screw holes being compatible, aligned and equal with the screw holes in the rigid metal bar cages (7) that fix the removable molds specially made for that production mold; and having the rigid metal bar cage (7) that fixes the removable molds on these molds. The vertical beam gap forming removable mold mentioned in request 1 is (3) and its feature is; In the production molds (1) of L-shaped connectors (5), T-shaped connectors (13) and +-shaped connectors (14), the arms are located in the center of the joint areas; their shapes are mostly hollow cylinders, but depending on the shape of the joint area, they have prismatic cavities with different cross-sections; their lengths are longer (higher) than the length of the production mold (1); they are rigid; their tops are open or the cavity-forming molds have removable covers (71); their bases are closed; they have screw holes in their bases; they have bars in their interior; they have screw holes (4) in the upper parts of the cavity-forming removable molds; It is characterized by the fact that the screw holes are on the upper surface of the cover of the cavity forming molds with removable covers (71); that these screw holes are compatible, aligned and equal to the screw holes in the rigid metal bar cages (7) fixing the removable molds specially made for that production mold; and that the rigid metal bar cage (7) fixing the removable molds is placed on these molds. The screw holes on the upper part of the removable molds mentioned in Request 1 are (4) and their feature is; It is characterized by the presence of removable moulds (2) for creating a gap, removable moulds (28) for producing flat blocks with rounded ends for half walls, which are placed in the corner areas, removable moulds (29) for creating a gap between two flat blocks with rounded ends for half walls and removable moulds (3) for creating a vertical beam gap or on the upper faces of the covers of moulds with removable covers (71); and the presence of a rigid metallic plate (9) with screw holes on the removable moulds (3) for creating a vertical beam gap. It is the longitudinal and transverse block cutting lines (6) mentioned in request 1, and its feature is; in the technical drawing, it is the lines to which the mirror command is applied, parallel to the OX axis positive direction and OY axis positive direction of the gas concrete element blocks; on the side face, it is characterized by the linear cutting lines parallel to the upper surface towards the opposite side face with intervals as much as the height of the masonry element block in the negative direction of the OZ axis. It is the rigid metal bar cage (7) fixing the removable molds mentioned in request 3, and its feature is; it is composed of rigid metal bars; these bars pass through the upper edges of the removable formworks (2), the flat block production formworks with rounded ends for half walls, the removable formworks (28) placed in the corner areas, the removable formworks between two flat blocks with rounded ends for half walls (29) and the vertical beam spacer removable formworks (3); It is characterized by having screw-hole rigid metallic plates (8) on rigid metal bars in the middle regions of the edges corresponding to the edges of the above-mentioned bars, except for the edges adjacent to the production mold (1), and in the regions where there are removable molds (3) forming the vertical beam gap, there is a screw-hole rigid metallic plate (9) of the removable mold forming the vertical beam gap. The L-shaped connector (5) mentioned in claim 1 is a multi-layer production mold (1) and its feature is that the length of the edges of the square surface of the square prism-shaped molds to be used is the same as the length of the inner edges of the arms of the L-shaped connector (5) to be formed; Arranging the removable molds (2) starting from the front left inner corner of the production mold (origin corner), in the positive OX axis direction and in the positive OY axis direction, with a distance between them of twice the thickness (width) of the flat blocks to be used in the region; forming rectangular prisms with a width equal to the side length of the square and twice the side length of the square, as a result of combining these removable molds (2) in the positive OX axis direction and in the positive OY axis direction with the mirror command on the sides; forming a large square prism in the middle region of each of the four virtual + shapes, as a result of combining these four small square prisms with the mirror command; the block cutting lines passing through the ends and midlines of the arms; It is characterized by separating the block into layers with horizontal cuts parallel to the upper surface in the negative direction of the OZ axis as much as the desired height. The T-shaped connector (13) mentioned in Request 1 is a multi-layered production mold (1) and its feature is; the length of the edges of the square surface of the square prism-shaped molds to be used is the same as the length of the inner edge of the arms of the T-shaped connector (13) to be formed; the removable molds (2) forming the gap are arranged in such a way that there is a distance between them as much as the width of the arms of the T-shaped connector (13) in the positive direction of the OY axis, starting from the front-left inner corner of the production mold, and a distance twice the width of the arms of the T-shaped connector (13) in the positive direction of the OX axis; This space is characterized by the formation of rectangular prisms with a width equal to the side length of the square and a length twice the side length of the square, formed as a result of the combination of the removable molds (2) on the sides, in the positive direction of the OX axis and in the positive direction of the OY axis, with the mirror command; the formation of a large square prism in the middle region of each of the four virtual + shapes, as a result of the combination of these four small square prisms with the mirror command; the block cutting lines passing through the ends of the arms parallel to the positive directions of the OX and OY axes, and the arms in the positive direction of the OY axis, passing through the middle of the arms parallel to the positive direction of the OY axis; the separation of the block into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the Z axis. The + shaped connector (14) mentioned in claim 1 is a multi-layered production mould (1) and its feature is; the length of the edges of the square surface of the square prism shaped removable spacer moulds (2) to be used is the same as the length of the inner edge of the arms of the + shaped connector (14) to be formed; the spacer removable moulds (2) are arranged starting from the front-left inner corner of the production mould, in the positive direction of the OX axis and in the positive direction of the OY axis, with a distance between them as long as the width of the arms of the + shaped connector (14); It is characterized by the following: the rectangular cross-section rectangular prisms, the width of which is the same as the side length of the square and the length of which is twice the side length of the square, formed as a result of the combination of these removable moulds (2) forming a space on the sides, in the positive direction of the OX axis and in the positive direction of the OY axis with the mirror command; the formation of a large square prism in the middle region of each of the four virtual + shapes, as a result of the combination of these four small square prisms with the mirror command; the block cutting lines passing from the ends of the arms, through the mirror lines; the separation into layers with horizontal cuts parallel to the upper surface as much as the desired height of the masonry element block in the negative direction of the OZ axis. l 1. The stepped flat block (1 5) multi-layer production mould (1) mentioned in claim 1, and its feature is; in the production mold (1), the lower step (16) and upper step (1 7) in the shape of a rectangular prism, called the cavity-forming removable mold (2), are present in both step regions; the step is located at the upper end of one end of the block and at the lower end of the other end; the height of this cavity is half the height of the flat block; these cavities, by merging at the end regions of the block in the positive direction of the OY axis and in the positive direction of the OX axis, form cavity-forming removable molds (2) in the shape of a long rectangular prism, with a volume twice as much; the formation of a common rectangular prism-shaped cavity-forming removable mold (2) in the middle line parallel to the line in the positive direction of the OX axis; It is characterized by the block cutting lines passing through the mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis of the blocks; separating the blocks into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. The unreinforced lintel (18) mentioned in Request 1 is a multi-layered production mold (1) and its feature is; in the production mold (1), there is a removable mold (2) in the shape of a rectangular prism, creating a gap, for each block next to each other, multiplied in the positive direction of the OY axis with the mirror command, in the common joint area; the width of this mold is 2 times the length of the arm of the lintel to be produced, and its length is as much as the distance between the arms of the lintel (19); the cutting lines passing through the mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; It is characterized by separating the block into layers in the negative direction of the OZ axis, with horizontal cuts parallel to the upper surface as much as the desired height of the block. The reinforced lintel (22) mentioned in claim 1 is a single-storey production mould (1) and its feature is; it contains reinforcement (20); in the production mould (1), there is a removable mould (2) in the shape of a rectangular prism, which creates a gap, for each two blocks side by side, which are multiplied in the positive direction of the OY axis with the mirror command, in the common joint area; the width of this mould is twice the length of the arm (19) of the lintel to be produced, and its length is as much as the distance between the arms (19) of the lintel; there are holes (21) in the main body of the reinforcement (20) and in the arms (19) of the lintel, at least one in each arm, for the screws to fix the reinforcement to be inserted; It is characterized by the cutting lines passing through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis. It is a multi-layered production mold (1) with single-walled flat block (23) with foamed filling regions mentioned in Claim 1 and its feature is; in the common joint area of 4 single-walled flat blocks (23) with foamed filling regions created by multiplying them first in the positive direction of the OY axis and then in the positive direction of the OX axis, there is a removable mold (2) in the shape of a rectangular prism that creates a gap; the upper area of this rectangular prism is 4 times the area of the rectangle existing in the inner area of the single-walled flat block (23) with foamed filling regions to be produced; the distance between the inner edge of the front or back wall of the production mold (1) and the end of the single wall (24) is as much as the height of the flat blocks to be used in the area; It is characterized by the block cutting lines passing through the middle line parallel to the line in the positive direction of the OX axis, and passing through the end of the single walls (24) and the lower surface of the body of the block, mirror lines parallel to the positive direction of the OY axis; It is characterized by separating the block into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. The foamed filling region and double-walled flat block (25) mentioned in Request 1 is a multi-layered production mold (1) and its feature is; The structure is multiplied in the positive direction of the OY axis with the mirror command, and then, with the application of the mirror command in the positive direction of the OX axis, a removable mold (2) in the shape of a rectangular prism forming a space in the common joint region; This spacer forming removable mould (2) is characterized by the fact that the area on the upper surface of the production mould (1) is twice the upper area of the rectangular prism shaped space between its two walls; the distance between the inner edge of the front or back walls of the production mould (1) and the end of the double walls is as much as the height of the flat blocks to be used in the area; the block cutting lines pass through the mirror lines in the positive direction of the OX axis and the positive direction of the OY axis; and the block is separated into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. The horizontal beam forming U block (26) mentioned in Claim 1 is a multi-layer production mould (1) and its feature is; There should be a rectangular prism shaped removable mold (2) in the common beam regions of two horizontal beam forming U blocks (26) copied with the mirror command in the positive direction of the OX axis; the length of the upper surface of this removable mold (2) should be the length of the rectangle on the lower surface of the horizontal beam forming U block (26) to be produced; there should be two rectangular prism shaped protrusion walls on the two side surfaces of this removable mold (2); the upper and lower of these protrusion shaped walls should be a thin rectangular shaped removable mold (2) in the corners between the walls of the production mold (1) and half the height of the block to be produced in the positive direction of the X axis; This mould is characterized by having a space in the form of a removable mould (2) that is the same length and twice the width between two horizontal beam forming U blocks (26) that are adjacent to each other in the positive direction of the OY axis; that the block cutting lines pass through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; that the block is separated into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. It is a multi-layered production mould (1) with a flat block (27) with rounded ends for the half wall mentioned in Request 1, and its feature is; in the production mould (1), in the positive direction of the Y axis, in the form of two blocks side by side and in the positive direction of the X axis, in the front-back neighborhood and in the shape of rectangular prisms with rounded ends adjacent to the production mould (1), the production moulds with rounded ends for the half-wall having the remaining gaps between them, the removable moulds (28) forming the gaps, placed in the corner areas, the removable moulds (29) forming the gap between the two flat blocks with rounded ends for the half-wall in the four inner corner areas of the production moulds (1), the common intermediate end area of the flat block with rounded ends for the two half-walls (2-7) and the side wall of the production mould (1); It is characterized by the presence of rigid metallic plates on the upper edges of these cavity forming molds, where the screw holes (4) are on the upper part of the removable cavity forming molds; the block cutting lines passing through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; and the separation into layers with horizontal cuts parallel to the upper surface as much as the desired height of the block in the negative direction of the OZ axis. It is a multi-layered production mold (1) with a wide upper side for the upper row of the half wall mentioned in Request 1, and its feature is; It is characterized by the following: after the mirror command is applied to the block in the positive direction of the OY axis, on the right and left outer sides, after the mirror command is applied in the positive direction of the OX axis, there is a removable mould (69) with quarter ellipse curved ends and a removable mould (70) with half ellipse curved ends in the middle region of four virtual aerated concrete elements adjacent to the front and back; the presence of rigid metallic plates with screw holes (4) on the upper parts of the removable moulds on the upper edges of these space forming moulds; the block cutting lines passing through the mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; and the separation of the block into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. The flat block (31) with skirting on both sides mentioned in Claim 1 is a multi-storey production mould (1) and its feature is that it contains two-sided skirting (32) on the lower two sides of the block; it is a production mould (1) belonging to a block whose length of horizontal arms is as thick as the skirting and whose height is as high as the height of the flat blocks to be used in the region; it is a removable mould (2) region forming two rectangular prism shaped spaces on the sides of the block completed to a rectangle with linear drawings made from both sides and bottom of this T-shaped imaginary block; after duplicating this block with the mirror command, first in the positive direction of the OY axis and then in the positive direction of the OX axis of the resulting structure, in the form of four blocks with the mirror command, a monoblock rectangular prism shaped space is formed between the outer side of the vertical arms of the T's and the inner surface of the walls of the production mold (1), the width and length of the first space is twice as long as the mold, parallel to the positive direction of the OX axis, a monoblock space is formed in the middle region of these four blocks, the width of the space is twice as long as the mold ... formed as a monoblock space is formed in the middle region of these four blocks, the monoblock space is formed in the middle region of these four blocks, the width of the space is formed on the sides, parallel to the positive direction of the space is formed, the width of the space is formed as a monoblock space is formed in the middle region of these four blocks, the monoblock space is formed in the middle region of the four blocks, the width of the space is twice as long as the mold, the width of the space is formed as a monoblock space is formed in the middle region of the four blocks, the monoblock space is formed in the middle region of the four blocks, the monoblock space is formed in the middle region of the four blocks, parallel to the positive direction of the space is formed as a monoblock space is formed in the positive direction of the space is formed. It is characterized by the block cutting lines passing through mirror lines parallel to the positive direction of the OX axis and the positive direction of the OY axis, and separating the block into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. The single-sided skirting flat block (33) mentioned in Request 1 is a multi-layered production mold (1) and its feature is; there is a single-sided skirting (34) on the lower edge of the block; the production mold (1) belonging to the single-sided skirting flat block (33), the length of the horizontal arm of which is as much as the thickness of the skirting and the height of the block is as much as the height of the flat blocks to be used in the region; the short edge of this L-shaped imaginary block is positioned in the region close to the positive direction of the OY axis, facing the opposite side edge of the production mold (1); This imaginary mold is characterized by the presence of a common space-forming removable mold (2) application area in the shape of a rectangular prism in the middle region of 4 blocks facing each other from the ends of the single-sided skirting board (34) in the positive direction of the OY axis and from the upper edges of the single-sided skirting board flat block (33) in the positive direction of the OX axis after the mirror command applied to the resulting structure first in the positive direction of the OY axis and then in the positive direction of the OX axis; the block cutting lines passing through the mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; and the block being separated into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of the OZ axis. The inner stepped column connection (35) for the double wall panel mentioned in Request 1 is a multi-layer production mold (1) and its feature is; inside, there is a virtual mould of aerated concrete element in the shape of a U positioned horizontally and its arms facing the opposite side edge of the production mould (1); the joints of the inner and outer corners of the U are 900; there is a gap called the inner step (37) in the form of a small rectangular prism for the double wall panel in the form of a step towards the outside at the end-inner part of its arms; this small gap is monoblock with the large gap in the centre; there is a large gap in the shape of a rectangular prism formed as a result of copying this virtual mould sideways in the positive direction of the OY axis with the mirror command; the block cutting lines pass through the mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; It is characterized by separating the block into layers with horizontal cuts parallel to the upper surface in the negative direction of the OZ axis as much as the desired height. The stepless arm connection (36) for the double wall panel mentioned in request 1 is a multi-layered production mold (1) and its feature is; there is a virtual mold of the gas concrete element in the shape of a U, positioned horizontally and the arms facing the opposite side edge of the production mold (1); the joints of the inner and outer corners of the U are 90°; there is a rectangular prism-shaped, removable mold (2) cavity in the common space region formed as a result of copying this virtual block in the positive direction of the OY axis with the mirror command; the block cutting lines pass through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; It is characterized by separating the block into layers with horizontal cuts parallel to the upper surface in the negative direction of the OZ axis as much as the desired height. The internal stepped beam connection (38) for the double wall panel mentioned in request 1 is a multi-layered production mold (1) and its features are; there is a U-shaped virtual mold positioned horizontally inside and the arms of which face the opposite side edge of the production mold (1); the joints of the outer corners of the U are 90°; the inner corners of the arms of the U, except for the sideways V part at the base, are 90°; the V part joins the edges of the U at an angle of 45°; the gap formed in the shape of the U is narrowed with a sideways V-shaped recess on the side; It is characterized by having a space called stepped column connection inner step (3 7) for double wall panel in the form of a small rectangular prism, in the end-inner part of its arms; this small space being monoblock with the large space in the center; containing a common prismatic space forming removable mold (2) applied to the space formed as a result of copying this virtual mold with the mirror command in the positive direction of OY axis; block cutting lines passing through mirror lines parallel to the positive direction of OX axis and parallel to the positive direction of OY axis; separating the block into layers with horizontal cuts parallel to the upper surface as much as the desired height in the negative direction of OZ axis. The stepped beam connection (39) for double wall panel mentioned in request 1 is a multi-layer production mold (1) and its feature is; inside, there is a U-shaped virtual mold positioned horizontally and the arms facing the opposite side edge of the production mold (1); the joints of the outer corners of the U are 90°; the inner corners of the arms of the U are 90° except for their joints with the edges of the lower, inverted V section; the base of the U is in the shape of a sideways V; the ends of the arms of this V shape make an angle of 45° with the arms of the U; this virtual mold contains a common prismatic cavity generator removable mold (2) applied to the cavity formed by copying it in the positive direction of the OY axis with the mirror command; the block cutting lines pass through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; It is characterized by separating the block into layers with horizontal cuts parallel to the upper surface in the negative direction of the Z axis as much as the desired height. The internal stepped base connection (40) for the double wall panel mentioned in request 1 is a multi-layered production mold (1) and its features are; there is a U-shaped virtual mold positioned horizontally inside and the arms of which face the opposite side edge of the production mold (1); the joints of the outer corners of the U are 90°; there is a V-shaped structure on the side of the production mold (1), which is tilted towards this U-shaped gap and whose opening faces this gap; the joint of the arms of the U with the arms of the V at the base is wide-angled; It is characterized by having a space called inner step (3 7) at the end-inner part of the arms, in the form of a step towards the outside, for a small prismatic double wall panel; this small space being monoblock with the big space in the center; containing a removable mold (2) applied to the common space formed as a result of copying this virtual mold with the mirror command in the positive direction of the OY axis; the block cutting lines passing through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; in the negative direction of the OZ axis, it is separated into layers with horizontal cuts parallel to the upper surface as much as the desired height of the block. The stepless base connection (41) for the double wall panel mentioned in claim 1 is a multi-layer production mold (1) and its feature is; inside, there is a U-shaped virtual mold positioned horizontally and its arms facing the opposite side edge of the production mold (1); the joints forming the outer corners of the U are 900; there is a V-shaped structure on the side of the production mold (1), leaning towards the outside of this U-shaped space, with its opening facing this space; the joint of the arms of the U with the arms of the V at the base is wide-angled; this virtual mold contains a prismatic cavity forming removable mold (2) applied to the common space formed as a result of copying it in the positive direction of the OY axis with the mirror command; the block cutting lines pass through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; It is characterized by separating the block into layers in the negative direction of the OZ axis, with horizontal cuts parallel to the upper surface as much as the desired height of the block. The flat blocks (42) with L connection plates mentioned in claim 1 are multi-layered production moulds (1) of the blocks used in the upper row (52) of the L connection plate system, and its feature is that the L connection plate is not used in this production mould (1); only on the inner face of the production mould (1), in the region corresponding to the bed (53) of the vertical extension of the L connection plate located in the lower half of the upper row and middle rows of the L connection plate system, in the middle part of its lower edge, the bed-forming apparatus's ... It is characterized by the fact that the stopper (56) of the bed forming apparatus, which has the screw holes (63) of the bed forming apparatus that will form the bed of the vertical extension of the L connection plate in the upper row in the L connection plate systems, is outside the production mold (1); these features are the same and symmetrical on the right and left sides of the production mold; the cutting lines pass through mirror lines parallel to the positive direction of the OX axis and parallel to the positive direction of the OY axis; and it is separated into layers with horizontal cuts parallel to the upper surface as much as the desired height of the block in the negative direction of the OZ axis. It is a single-layer production mold belonging to the lower row (73) of the L connection plate system mentioned in Request 1, and its feature is; The lower half of the lower row of the L connection plate system (46) and the upper half of the lower row of the L connection plate system (48) are formed by the monoblock connection of two sections; the lower half of the lower row of the production mold (1), the lower half of the lower row of the L connection plate system (46), is no different from standard classical flat blocks; starting from the lower middle part of the upper half, on the inner surface of the production mold (1), the vertical arm (44) of the L connection plate extends towards the upper edge of the production mold (1), as if it were stuck to the inner surface of the production mold (1); in this position, the horizontal arm (43) of the L connection plate extends towards the inside (middle) of the production mold (1); It is characterized by the presence of gas concrete mortar passage holes (45) on the horizontal arm of the L connection plate (43); the plate-shaped part of the vertical arm of the L connection plate (44), which is located on the upper part of the upper edge of the production mould (1) and contains the screw holes (59) to which the vertical arm of the L connection plate will be screwed to the column, being on the inner surface of the plate-shaped elevation (58) to which the end of the vertical arm of the L connection plate is screwed on the upper edge of the production mould and being back-to-back with it; being screwed with it through the screw holes; the aforementioned features being the same and symmetrical on the right and left sides of the production mould; the block cutting lines being along the mirror lines parallel to the positive direction of the OY axis and parallel to the positive direction of the OX axes. It is a single-storey production mould (1) belonging to the middle rows (74) of the L connection plate system mentioned in claim 1, and its feature is; it is formed by the monoblock combination of the lower half of the middle rows (49) of the L connection plate system and the upper half of the middle rows (51) of the L connection plate system; it contains two blocks multiplied with the mirror command in the positive direction of the OY axis and a large number of blocks multiplied with the mirror command in the positive direction of the OX axis; on the middle rows of L connection plate systems, the removable metal plate (64) forming the bearing of the vertical extension of the L connection plate, which will form the bearing of the vertical extension of the L connection plate, starting from the middle part of the lower edge of each block area and continuing up to 1# of the block height; It is characterized by the fact that the plate-shaped part of the vertical arm of the L connection plate (44), which is located on the upper part of the upper edge of the production mould (1) and contains the screw holes (59) to which the vertical arm of the L connection plate will be screwed to the column, is on the inner face of the plate-shaped elevation (58) to which the end of the vertical arm of the L connection plate is screwed to the upper edge of the production mould and runs back to back with it; it is connected to it with the screw holes (59) to which the vertical arm of the L connection plate will be screwed to the column; these features are the same and symmetrical on the right and left side faces of the production mould (1); the block cutting lines are along the mirror lines parallel to the positive direction of the OY axes and parallel to the positive direction of the OX axis. It is a removable mould (60) that reduces the width of the production mould mentioned in claim 1, and its feature is; in the production moulds (1), it is located on the side inner face of the production mould (1), in the positive direction of the OX axis; it is a hollow, rigid mould; it is open-top or cavity-forming moulds have removable covers (71); the upper edge of the ones with open tops is higher than the upper edge of the production mould (1); on the inner-upper edge of the removable mould (61), in the production moulds of the lower and middle rows of L connection plate systems (1), there are plate-shaped elevations (58) to which the end of the vertical arm of the L connection plate is screwed on the upper edge of the production mould; It is characterized by the presence of plate-shaped elevations (58) on the upper inner edge of the ones with removable covers (71) of the cavity-forming molds to which the end of the vertical arm of the L connection plate is screwed on the upper edge of the production mold; it is characterized by the fact that the removable mold (60), which narrows the width of the production mold when necessary, consists of several short molds cut crosswise. It is a removable mold (62) that shortens the length of the production mold mentioned in request 1 and its feature is; in the production molds it is located in, it is located on the front or back inner face of the production mold (1), in the positive direction of the OY axis; it is a hollow, rigid mold; it is open-top or cavity-forming molds with removable covers (71); It is characterized by the upper edge of the open-top ones being higher than the upper edge of the production mold (1); It is composed of several short molds cut transversely to the removable mold (62) that shortens the length of the production mold when necessary. It is a removable mold (72) that creates a gap that reduces the depth of the production mold mentioned in claim 1 or 2, and its feature is; It is a rectangular prism-shaped, hollow, rigid mold; It is characterized by being placed between the upper face of the base of the production mold (1) and the additional metallic plate (66) placed on the base of the production mold. It is the additional metallic plate (66) to be placed on the base of the production mold mentioned in claim 1, and its feature is; It is a removable, multi-use rigid metal plate; It is characterized by the presence of screw holes (67) on the additional metallic plate, where the removable molds that create the space are fixed, and screw holes (68) on the additional metallic plate.