JP2019181918A - Building cement brick production processing device - Google Patents

Abstract

To disclose a building cement brick production processing device.SOLUTION: A device of the present invention includes a base, a guide rail housing in which an opening is upward and the right side is connected to the outside in the base, a sliding frame that can slide left and right on the left side of the guide rail, a fixed block installed symmetrically on an upper end surface of the sliding frame, a first guide lever for fixedly attaching between two fixing blocks, a positioning block on the right side of the sliding frame mounted and fixed to a bottom wall of the guide rail housing, a drive electric machine for fixedly mounted in a left end wall of the guide rail housing, a screw shaft for engaging and attaching in the sliding frame with a screw, a right end of the screw shaft for mounting around the positioning block, a left end of the screw shaft for connecting to the drive electric machine by power, a push block installed symmetrically on the right side of a positioning block, and a guide block for fixedly installing on both left and right end surfaces of the push block.SELECTED DRAWING: Figure 1

Description

  The present invention relates to the field of building material processing, and more specifically to building cement brick production and processing equipment.

Cement bricks are a new type of wall made by high-temperature firing, using fly ash, coal slag, coal veins, tailings slag, chemical slag or natural sand, sea mud, etc. (one or several of the above raw materials) as a coagulant. It is a material.

Cement bricks are lightweight, high in strength, do not need to be fired, are made of fly ash from power plants, are relatively environmentally friendly, and have high strength, durability, and dimensional standards. Has gained a high reputation. The shape is perfect, the color is uniform, it has a simple and natural appearance and can be used as a transparent water wall or any exterior. Therefore, it is a promising alternative product for replacing clay bricks.

However, many of the conventional cement brick processing equipment has to be completed manually, and there is a problem that the processing cost of cement bricks increases due to the high dependence on human power and soaring labor costs. The processing efficiency of typical processing equipment is low, the quality of cement bricks is degraded, and it cannot be built.

Chinese Patent Application No.102464816 Specification

  An object of the present invention is to provide a building cement brick production and processing facility for solving the problems submitted to the background art described above.

  The building cement brick production and processing equipment of the present invention includes a base, a guide rail housing having an opening upward and a right side connected to the outside is installed in the base, and a sliding frame that can slide to the left and right is provided on the left side of the guide rail. A fixed block is installed symmetrically on the upper end surface of the sliding frame, a first guide lever is fixedly attached between the two fixed blocks, and is attached to the bottom wall of the guide rail housing on the right side of the sliding frame. A positioning block is fixedly mounted, a driving electric machine is fixedly mounted in the left end wall of the guide rail housing, a screw shaft is engaged and mounted in the sliding frame with a screw, and a right end of the screw shaft is positioned in the positioning It is attached around the block, the left end is connected to the drive electric machine by power, the push block is installed symmetrically on the right side of the positioning block, The guide block is fixedly installed on the left and right end faces of the block, the second guide lever is slidably mounted on the guide block, and the front and rear ends of the second guide lever are separately connected to the front and rear end walls of the guide rail housing. A transfer groove connected up and down is installed on the end face facing the push block, a push slant groove connected to the transfer groove is relatively installed on the two push blocks, and a support block is installed on an upper end of the push block, A push slope that engages with the push diagonal groove is installed symmetrically on the lower end surface of the support block, a stopper groove is installed in the support block, a stopper block is slidably mounted in the stopper groove, and the stopper A column extending downward is fixedly attached to the lower end of the block, and the lower end of the column penetrates the stopper groove and the guide From left to right on the right side of the push block that is fixedly connected to the bottom wall of the rail housing and installed in the guide rail housing, the mold mounting process, the first injection process, the first punching process, the second injection Process and a second punching process are installed, and a sandwich arm that extends horizontally on the second guide lever is slid in each push block, and the left end of the sandwich arm is between two fixed blocks. Extending and slidingly engaged with the first guide lever, and sandwiched between the end face facing the pinching arm and the mold mounting process, the first injection process, the first punching process, and the second injection process and the second punching process. A friction block is attached.

The first support spring is fixedly attached to the upper end surface of the stopper block, and the upper end of the first support spring is fixedly connected to the top wall of the stopper groove. Insert it on top.

Further, the second support spring fixedly connected to the push block is fixedly attached to the front and rear end walls of the guide rail housing, and the two push blocks are brought close to each other by the second support spring, and the push diagonal A groove is engaged with the push slope.

Further technical plan, distance between the mold mounting process and the first injection process, distance between the first injection process and the first punching process, distance between the first punching process and the second injection process, second injection process and second The distance of the punching process is the same, and the maximum distance between the sliding frame and the positioning block is the same as the distance between the mold mounting process and the first injection process.

Further technical plan, a transport machine is installed on the right side of the base, convenient for moving cement brick products to be punched second.

Further technical plan, a lifting frame is installed on the base, and it corresponds to the mold mounting process, first injection process, first punching process, second injection process and second punching process in the lifting frame. A mold mounting housing, a first injection machine, a first punching machine, a second injection machine and a second punching machine are installed.

The beneficial effect of the present invention is that when the device of the present invention is used, the two holding arms are divided by the support block, and the two holding arms are tightened by the action of the first spring and the second spring, As a result, it is realized that the cement mold is loosened and pinched, and the action of the driving electric machine moves the pinching arm through the screw shaft and pushes it to the right, whereby the cement mold is mounted on the mold. In order from the first injection process, the first punching process, the second injection process and the second punching process, the cement mold is the first injection process, the first punching process, the second injection process and the second punching process. When moved to the process, the first injection machine, the first punching machine, the second injection machine and the second punching machine are the first injection process, the first punching process, the second injection process, while the lifting frame is lowered Second punching process A cement mold is first-injected, first-punched, second-injected, and second-punched, and the second-punched cement-mold is slid down and moved to the transport machine, so that the structure of the device of the present invention is simple. It is convenient to use, has a high level of automation, and improves the quality of cement brick and improves the processing efficiency of cement brick through the two injections and punching.

In order to more clearly explain the technical solutions in the embodiments of the present invention and in the existing technology, the following is a brief introduction to the accompanying drawings that need to be used in the description of the embodiments and the existing technology. It should be understood that the accompanying drawings in the following description are only some embodiments of the present invention, and that other engineers based on these appended drawings are assumed based on the assumption that creative labor is not paid to ordinary engineers in this field. Attached figure can be obtained.

It is a structural schematic diagram of the building cement brick production processing equipment of this invention. FIG. 2 is a structural schematic diagram of a push block in the arrow direction of FIG.

All features disclosed in the present invention, or all disclosed methods and steps in the process, may be combined in any manner other than features or steps that are mutually exclusive.

All features disclosed in the present invention may be replaced with other equivalent features having equivalent or similar purposes unless otherwise specified. That is, unless otherwise stated, all features are just one example in a series of equivalent or similar features.

As shown in FIGS. 1 to 2, the building cement brick production and processing equipment of the apparatus of the present invention includes a base 10, and a guide rail casing 11 having an opening upward and a right side connected to the outside is installed in the base 10. A sliding frame 27 that can slide left and right is attached to the left side of the guide rail 11, a fixed block 25 is installed symmetrically on the upper end surface of the sliding frame 27, and a first guide lever 30 is provided between the two fixed blocks 25. Is fixedly attached to the bottom wall of the guide rail housing 11, the positioning block 31 on the right side of the sliding frame 27 is fixedly attached, and the drive electric machine 28 is fixedly attached to the left end wall of the guide rail housing 11. The screw shaft 29 is engaged and attached to the sliding frame 27 with a screw, the right end of the screw shaft 29 is attached to the positioning block 31 and the left end is connected to the driving electrical machine 28 by power, and the positioning block The push block 21 is installed symmetrically on the right side of the rack 31, the guide block 13 is fixedly installed on the left and right end faces of the push block 21, and the second guide lever 23 is slidably attached to the guide block 13. The front and rear ends of the two guide levers 23 are separately fixedly connected to the front and rear end walls of the guide rail housing 11, and a transfer groove 35 that is vertically connected to the end face facing the push block 21 is installed. A push slant groove connected to the transfer groove 35 is relatively installed, a support block 22 is installed at the upper end of the push block 21, and a push slope 37 that engages the push slant groove on the lower end surface of the support block 22 is symmetric in the longitudinal direction. A stopper groove 32 is installed in the support block 22, a stopper block 34 is slidably mounted in the stopper groove 32, and extends downward to the lower end of the stopper block 34. The column 36 is fixedly attached, and the lower end of the column 36 penetrates the stopper groove 32 and is fixedly connected to the bottom wall of the guide rail housing 11, and the push rail installed in the guide rail housing 11 From left to right on the right side of the block 21, a mold mounting process 20, a first injection process 19, a first punching process 18, a second injection process 17 and a second punching process 16 are installed. A sandwiching arm 24 extending left and right on the second guide lever 23 is slid and attached, and the left end of the sandwiching arm 24 extends between two fixed blocks 25 and is slidably engaged with the first guide lever 30. The pinch friction block 14 is attached to the end face facing the pinch arm 24 and the mold mounting step 20, the first injection step 19, the first punching step 18, the second injection step 17 and the second punching step 16. .

As a useful example, a first support spring is fixedly attached to an upper end surface of the stopper block 34, and an upper end of the first support spring is fixedly connected to a top wall of the stopper groove 32, and the first support spring is fixed. The support block 22 is inserted upward with a spring.

As a beneficial example, a second support spring fixedly connected to the push block 22 is fixedly attached to the front and rear end walls of the guide rail housing 11, and the two push blocks 21 are fixed by the second support spring. And the pushing slant groove is engaged with the pushing slope 37.

As a useful example, the distance between the mold mounting step 20 and the first injection step 19, the distance between the first injection step 19 and the first punching step 18, the first punching step 18 and the second injection step 17 The distance between the second injection step 17 and the second punching step 16 is the same, and the maximum distance between the sliding frame 27 and the positioning block 31 is the same as the distance between the mold mounting step 20 and the first injection step 19 It is.

As a useful example, a transport machine 15 is installed on the right side of the base 10 and is convenient for moving cement brick products that are second punched.

As shown in a useful example, a lifting frame is installed on the base 10, and the mold mounting step 20, the first injection step 19, the first punching step 18, and the second injection step are installed in the lifting frame. Corresponding to 17 and the second punching process 16, a mold mounting housing, a first injection machine, a first punching machine, a second injection machine and a second punching machine are installed.

When the present invention is in an initial state, the sliding frame 27 comes into contact with the left end of the guide rail housing 11, and the support block 22 is inserted upward by the action of the first support spring, and the second support spring. As a result, the two push blocks 21 are brought close to each other, and the push oblique grooves are engaged with the push slope 37.

When using, put cement brick into the mold mounting case, inject concrete into the first and second syringes, move the lifting frame and slide down, the lifting frame descends During the process, the elevating frame inserts the support block 22 downward, the support block 22 separates the two front and rear push blocks 21, and the two push blocks 21 move the two sandwiching arms 24 apart. When the cement mold falls into the mold mounting step 20 in the mold mounting housing, the lifting frame is moved up and raised, and the lifting frame is improved, the first support spring and the second By the action of the support spring 12, the support block 22 slides up, the two push blocks 21 approach each other and the sandwiching arm 24 is moved and brought close, thereby sandwiching the cement mold with the sandwiching friction block 14, When the lifting frame reaches the top, The drive electrical machine 28 is started, the drive electrical machine 28 moves and rotates the screw shaft 29, the screw shaft 29 moves the sliding frame 27 and slides to the right, and the sliding frame 27 contacts the positioning block 31. When the screw shaft 29 is moved and rotated in the reverse direction, the cement mold is moved to the first injection process, the elevating frame is moved and moved downward, and the elevating frame is moved downward. The support block 22 is again moved and slid down, the cement mold in the mold mounting housing falls again into the mold mounting process, and the first injection machine is in the first injection process 19 After injecting concrete into the cement mold, the lifting frame is moved again and slid up, and the operation of the drive electric machine 28 is repeated, whereby the cement mold is moved from the mold mounting step 20 in order. One injection process 19, first punching process 18, second note When the cement mold is moved to the first injection process 19, the first punching process 18, the second injection process 17 and the second punching process 16, the lifting and lowering is performed. While the frame is lowered, the first injection machine, the first punching machine, the second injection machine and the second punching machine are in the first injection process 19, the first punching process 18, the second injection process 17 and the second punching process 16. A certain cement mold is subjected to a first injection, a first punch, a second injection, and a second punch, and the second punched cement mold is slid down to the transport machine 15 and moved.

The basic principle, main features and advantages of the present invention have been described and explained above. It should be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and the above-described embodiments and the description are the principles of the present invention, and do not depart from the significance and principles of the present invention. There are various changes and improvements in the present invention on the premise, and these changes and improvements are within the protection scope of the present invention. The scope of protection of the present invention is defined as equivalent to the attached rights request.

Claims (1)

The building cement brick production and processing equipment includes a base, a guide rail housing having an opening upward and a right side connected to the outside is installed in the base, and a sliding frame that can slide left and right is attached to the left side of the guide rail, A fixed block is installed symmetrically on the upper end surface of the sliding frame, a first guide lever is fixedly attached between the two fixed blocks, and a positioning block located on the right side of the sliding frame on the bottom wall of the guide rail housing Is fixedly mounted, a drive electric machine is fixedly mounted in the left end wall of the guide rail housing, a screw shaft is engaged and mounted in the sliding frame with a screw, and a right end of the screw shaft rotates around the positioning block. Attached, the left end is connected to the drive electric machine by power, the push block is installed symmetrically on the right side of the positioning block, and the push block Guide blocks are fixedly installed on both left and right side surfaces of the bracket, a second guide lever is slidably mounted on the guide block, and the front and rear ends of the second guide lever are separately connected to the front and rear end walls of the guide rail housing. A transfer groove that is vertically connected to the end face facing the push block, a diagonal push groove that is connected to the transfer groove is relatively installed on the two push blocks, and a support block is installed on an upper end of the push block. A push slope that engages with the push diagonal groove is installed symmetrically on the lower end surface of the block, a stopper groove is installed in the support block, a stopper block is slidably mounted in the stopper groove, and the stopper block A support column extending downward is fixedly attached to the lower end of the guide rail, and the lower end of the support column penetrates the stopper groove and the guide rail. From the left to the right on the right side of the push block that is fixedly connected to the bottom wall of the body and installed in the guide rail housing, the mold mounting process, the first injection process, the first punching process, the second injection process, and A second punching step is installed, and a left and right extending sandwiching arm on the second guide lever is slid into each push block, and the left end of the sandwiching arm extends between two fixed blocks. An end face that is slidably engaged with the first guide lever and faces the sandwiching arm and a friction block sandwiched between the mold mounting step, the first injection step, the first punching step, and the second injection step and the second punching step. The first support spring is fixedly attached to the upper end surface of the stopper block, and the upper end of the first support spring is fixedly connected to the top wall of the stopper groove. The support block is inserted upward, and a second support spring fixedly connected to the push block is fixedly attached to the front and rear end walls of the guide rail housing. Approaching, engaging the push oblique groove with the push slope, the distance between the mold mounting step and the first injection step, the distance between the first injection step and the first punching step, the first punching step and the second injection The distance of the process, the distance of the second injection process and the second punching process are the same, the maximum distance of the sliding frame and the positioning block is the same as the distance of the mold mounting process and the first injection process, A transport machine is installed on the right side of the second, which is convenient for moving cement brick products to be punched second, a lifting frame is installed on the base, the mold mounting step in the lifting frame, the first injection Process, first Chi punching step, the second injection step and corresponding to the second punching step the mold mounting housing, the first injection machine, the first punching machine, the second injection machine and the second punching device is installed.

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