CN220994842U - High-efficient forming device of non-clay sintering porous brick - Google Patents

Abstract

The utility model relates to the technical field of porous brick molding, and discloses a high-efficiency molding device for non-clay sintered porous bricks, which comprises a base, wherein a shaping box is fixedly connected to the center of the top of the base, a placing groove is formed in the shaping box, the upper surface of the interior of the placing groove is communicated with the outside, a die carrier is connected in the placing groove in a sliding manner, a shaping interval is formed between the die carrier and the interior of the placing groove, and a plurality of uniformly distributed fixing rods are fixedly connected to the lower surface of the interior of the placing groove at the position corresponding to the shaping interval; the device is convenient for carry out jacking drawing of patterns through the die carrier of the inside sintering perforated brick of jacking subassembly after the shaping when using to make the device be convenient for carry out quick drawing of patterns to the sintering perforated brick that its design was accomplished and handle, and avoid artificial drawing of patterns to lead to the sintering perforated brick to produce the damage easily, and avoid influencing staff's normal processing effect, and then avoid causing unnecessary loss.

Description

High-efficient forming device of non-clay sintering porous brick

Technical Field

The utility model relates to the technical field of porous brick molding, in particular to a high-efficiency molding device for non-clay sintered porous bricks.

Background

The sintered porous brick is a brick which is formed and baked by taking clay, shale and fly ash as main raw materials, has a hole rate equal to or more than 15%, has holes which are round holes or non-round holes, has small holes and a large number of holes, and is mainly suitable for bearing walls. And the porous brick is formed by using a forming device. However, most of the existing high-efficiency forming devices for non-clay sintered porous bricks are inconvenient to demould when in use, workers cannot rapidly demould the shaped porous bricks when in use, and artificial demould easily causes damage to the porous bricks, influences the normal processing effect of the workers and causes unnecessary loss.

Disclosure of utility model

The utility model mainly solves the technical problem of providing a high-efficiency forming device for non-clay sintered porous bricks, which can solve the problems in the background technology.

In order to solve the technical problem, according to one aspect of the utility model, the efficient forming device for the non-clay sintered porous bricks comprises a base, wherein a forming box is fixedly connected to the center of the top of the base, a placing groove is formed in the forming box, the upper surface of the inside of the placing groove is communicated with the outside, a die frame is slidably connected in the placing groove, a forming section is formed between the die frame and the inside of the placing groove, a plurality of uniformly distributed fixing rods are fixedly connected to the position, corresponding to the forming section, of the lower surface of the inside of the placing groove, a jacking component is arranged in the base, the jacking component is installed with the die frame, a lifting component is arranged in the center of the rear surface of the forming box, a pressing plate is arranged at the bottom of the lifting component, and a plurality of uniformly distributed pressing blocks are fixedly connected to the bottom of the pressing plate.

Furthermore, the jacking component comprises a first inner groove arranged at the inner center of the base, a third inner groove is arranged at the center of the lower surface of the first inner groove, a first motor is fixedly connected with the lower surface of the third inner groove, the output end of the first motor is fixedly connected with a second rotating rod, a second slot is arranged at the center of the upper surface of the first inner groove, the top end of the second rotating rod is inserted into the second slot and is rotationally connected with the second slot, a fourth helical gear is fixedly connected below the outer surface of the second rotating rod, the left side and the right side of the fourth helical gear are respectively connected with a third helical gear in an engaged manner, the left side and the right side of the first inner groove are respectively fixedly connected with a fixing plate, a left through type through hole is formed at the center of the inner part of the fixing plate, the first rotating rod is rotationally connected with the inside of the through hole through a bearing, the end of the rotating rod I, which is close to the inner center of the inner groove I, is fixedly connected with one side of the bevel gear III, which is far away from the inner center of the inner groove I, the end of the rotating rod I, which is far away from the inner center of the inner groove I, is fixedly connected with the bevel gear II, the top of the bevel gear II is in meshed connection with the bevel gear I, the left and right sides of the upper surface of the inner groove I are provided with through grooves I, the left and right sides of the top of the base is fixedly connected with support columns, the inner groove II is provided with inner grooves II, the lower surface of the inner groove II is communicated with the inner part of the through grooves I, the center of the upper surface of the inner groove II is provided with a slot I, the upper part, which is close to the inner center of the base, of the inner groove II is provided with a left and right through groove II, the inner part of the through groove II is in a sliding connection with a transverse plate, the bottom of the transverse plate is fixedly connected with a connecting block at the corresponding part of the top of the die carrier, the bottom of the connecting block is fixedly connected with the top of the die carrier, the transverse plate is internally provided with a threaded hole penetrating through the inside of the inner groove II, the threaded hole is internally connected with a threaded rod in a threaded manner, the top end of the threaded rod is inserted into the slot I and is rotationally connected with the slot, the bottom end of the threaded rod penetrates through the slot I and is rotationally connected with the slot I through a bearing, and the threaded rod is fixedly connected with the center of the top of the bevel gear.

Still further, the lifting component includes fixed connection in bracing piece of shaping box rear surface center department, inside four of inside top of bracing piece has been seted up, just inside four inside upper surfaces of inside communicate with each other with the outside, four inside lower surface fixedly connected with motors two of inside, motor two output fixedly connected with dwang is three, the top of dwang is three runs through the top of bracing piece, and fixedly connected with backup pad, fixed surface is connected with the connecting plate before the backup pad, the through-hole that runs through from top to bottom has been seted up in the inside place ahead of connecting plate, connecting plate top fixedly connected with electric lifting rod, electric lifting rod's output runs through the through-hole, and with the top fixed connection of pressing plate.

Further, the top end of the supporting rod is attached to the bottom of the supporting plate.

Further, the bottom of the connecting plate is attached to the top of the pressing plate.

Further, the bottom of the pressing block corresponds to the shaping interval.

The efficient forming device for the non-clay sintered porous bricks has the beneficial effects that:

the device is convenient for carry out jacking drawing of patterns through the die carrier of the inside sintering perforated brick of jacking subassembly after the shaping when using to make the device be convenient for carry out quick drawing of patterns to the sintering perforated brick that its design was accomplished and handle, and avoid artificial drawing of patterns to lead to the sintering perforated brick to produce the damage easily, and avoid influencing staff's normal processing effect, and then avoid causing unnecessary loss, and make the device convenient to use, and the practicality is stronger.

Drawings

The utility model will be described in further detail with reference to the accompanying drawings and detailed description.

FIG. 1 is a schematic diagram showing the front perspective view of a device for efficiently forming non-clay sintered porous bricks;

FIG. 2 is a schematic view of a rear top perspective view of a high efficiency forming apparatus for non-clay sintered porous bricks according to the present utility model;

FIG. 3 is a schematic diagram showing the structure of a device for efficiently forming non-clay sintered porous bricks in front section;

FIG. 4 is an enlarged schematic view of the structure of the non-clay sintered porous brick high-efficiency forming device shown in FIG. 3A;

Fig. 5 is a schematic diagram of a front sectional structure of a supporting rod of the high-efficiency forming device for non-clay sintered porous bricks.

In the figure: 1. a base; 2. a jacking assembly; 201. an inner groove I; 202. a first helical gear; 203. a first through groove; 204. a threaded rod; 205. a support column; 206. an inner groove II; 207. a cross plate; 208. a first slot; 209. a second through groove; 210. a helical gear II; 211. rotating the first rod; 212. a fixing plate; 213. a helical gear III; 214. a second slot; 215. a second rotating rod; 216. helical gears IV; 217. a first motor; 218. an inner groove III; 219. a through hole; 220. a threaded hole; 221. a connecting block; 3. a shaping box; 4. a placement groove; 5. a mould frame; 6. setting an interval; 7. a fixed rod; 8. a lifting assembly; 801. a connecting plate; 802. an electric lifting rod; 803. a support plate; 804. a support rod; 805. a through hole; 806. an inner groove IV; 807. a second motor; 808. rotating a rod III; 9. pressing the blocks; 10. pressing the plate.

Detailed Description

The utility model will be described in detail hereinafter with reference to the drawings in conjunction with embodiments. It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

As shown in fig. 1 to 4, according to one aspect of the present utility model, there is provided a high-efficiency molding device for non-clay sintered porous bricks, comprising a base 1, a molding box 3 fixedly connected to the center of the top of the base 1, a holding tank 4 provided inside the molding box 3, the upper surface inside the holding tank 4 being communicated with the outside, a mold frame 5 slidingly connected inside the holding tank 4, a molding space 6 formed between the mold frame 5 and the inside of the holding tank 4, a plurality of uniformly distributed fixing rods 7 fixedly connected to the lower surface inside the holding tank 4 at positions corresponding to the molding space 6, a jacking component 2 provided inside the base 1, the jacking component 2 being mounted with the mold frame 5, a lifting component 8 provided at the center of the rear surface of the molding box 3, a pressing plate 10 provided at the bottom of the lifting component 8, a plurality of uniformly distributed pressing blocks 9 fixedly connected to the bottom of the pressing plate 10, when in use, firstly, the bottom of the base 1 of the device is placed on a flat ground, after being placed firmly, raw materials are placed in a shaping zone 6 formed between a die carrier 5 in the shaping box 3 and the inside of a placing groove 4, holes for sintering porous bricks are formed through a fixing rod 7, then in the sintering process, a pressing plate 10 and a pressing block 9 are driven by a lifting component 8 to press the sintering porous bricks in the shaping zone 6, and after the sintering is finished, the die carrier 5 is convenient to move and demould through a jacking component 2, so the device is convenient for the die carrier 5 to lift and demould after the shaping of the sintering porous bricks in the shaping box 3 through the jacking component 2 when in use, thereby the device is convenient for carrying out quick demoulding treatment on the sintering porous bricks after the shaping is finished, the sintering porous bricks are prevented from being damaged easily due to artificial demoulding, and the normal processing effect of workers is prevented from being influenced, further avoid causing unnecessary loss, and make the device convenient to use, and the practicality is stronger.

In this embodiment, the jacking component 2 includes a first inner groove 201 formed at the inner center of the base 1, a third inner groove 218 formed at the center of the inner lower surface of the first inner groove 201, a first motor 217 fixedly connected to the inner lower surface of the third inner groove 218, a second rotating rod 215 fixedly connected to the output end of the first motor 217, a second slot 214 formed at the center of the inner upper surface of the first inner groove 201, a fourth bevel gear 216 inserted into the second slot 214 and rotatably connected to the second slot 214, a third bevel gear 213 meshed with the left and right sides of the fourth bevel gear 216 and fixedly connected to the lower portion of the outer surface of the second rotating rod 215, the left and right sides of the inner part of the first inner groove 201 are fixedly connected with a fixed plate 212, the center of the inner part of the fixed plate 212 is provided with a left and right penetrating type through hole 219, the inside of the through hole 219 is rotatably connected with a first rotating rod 211 through a bearing, one end of the first rotating rod 211, which is close to the center of the inner part of the first inner groove 201, is fixedly connected with one side of the third bevel gear 213, which is far away from the center of the inner part of the first inner groove 201, one end of the first rotating rod 211, which is far away from the center of the inner part of the first inner groove 201, is fixedly connected with a second bevel gear 210, the top of the second bevel gear 210 is in meshed connection with a first bevel gear 202, the left and right sides of the upper surface of the inner part of the first inner groove 201 are provided with a first through groove 203 which penetrates vertically, the left side and the right side of the top of the base 1 are fixedly connected with support columns 205, an inner groove II 206 is formed in the support columns 205, the lower surface of the inner groove II 206 is communicated with the inner part of the through groove I203, a slot I208 is formed in the center of the upper surface of the inner groove II 206, a left-right through groove II 209 is formed in the inner part of the inner groove II 206, which is close to the upper part of the inner center of the base 1, a transverse plate 207 is slidingly connected in the through groove II 209, a connecting block 221 is fixedly connected at the position corresponding to the top of the die carrier 5 at the bottom of the transverse plate 207, the bottom of the connecting block 221 is fixedly connected with the top of the die carrier 5, a threaded hole 220 which penetrates up and down is formed in the inner part of the inner groove II 206, the threaded hole 220 is internally and in threaded connection with a threaded rod 204, the top end of the threaded rod 204 is inserted into the first slot 208 and is in rotary connection with the first slot 208, the bottom end of the threaded rod 204 penetrates through the first slot 203 and is in rotary connection with the first slot 203 through a bearing and is fixedly connected with the center of the top of the first bevel gear 202, when the jacking component 2 is used for demolding the mold frame 5, the first motor 217 is firstly connected with an external power supply to start the first motor 217, the second motor 217 drives the second rotary rod 215 to rotate after working and drives the fourth bevel gear 216 and the third bevel gear 213 in meshed connection with the fourth bevel gear after the second rotary rod 215 rotates, then, the third helical gear 213 rotates to drive the first rotary rod 211 to rotate, the first rotary rod 211 rotates to drive the second helical gear 210 and the first helical gear 202 in meshed connection with the first helical gear 202 to rotate, the first helical gear 202 rotates to drive the threaded rod 204 to rotate, the threaded rod 204 rotates to drive the transverse plate 207 to move under the limit of sliding connection with the second through groove 209, the transverse plate 207 moves to drive the connecting block 221 to move, so that the connecting block 221 can move to drive the die frame 5 to move out of the placing groove 4 for demolding, and the die frame 5 can move up and down through the first motor 217 capable of rotating positively and negatively.

In this embodiment, the lifting assembly 8 includes a supporting rod 804 fixedly connected to the center of the rear surface of the shaping box 3, an inner groove four 806 is formed above the inner portion of the supporting rod 804, and the upper surface of the inner groove four 806 is communicated with the outside, a motor two 807 is fixedly connected to the lower surface of the inner groove four 806, the output end of the motor two 807 is fixedly connected to a rotating rod three 808, the top end of the rotating rod three 808 penetrates through the top of the supporting rod 804 and is fixedly connected to a supporting plate 803, the front surface of the supporting plate 803 is fixedly connected to a connecting plate 801, a penetrating hole 805 penetrating up and down is formed in the front of the inner portion of the connecting plate 801, the top of the connecting plate 801 is fixedly connected to an electric lifting rod 802, the output end of the electric lifting rod 802 penetrates through the penetrating hole 805 and is fixedly connected to the top of the pressing plate 10, when the lifting assembly 8 is used, the electric lifting rod 802 is connected to an external power source through the electric lifting rod 802 so that the electric lifting rod 802 works to drive the pressing plate 10 to move, and the motor two 807 works to drive the rotating rod three 808 and the supporting plate 801 and the electric lifting rod 802 to rotate through the motor two 807 to the external power source, and the pressing plate 801 is further to rotate away from the top of the shaping box 3.

In this embodiment, the top end of the supporting rod 804 is attached to the bottom of the supporting plate 803, and when in operation, the supporting plate 803 can rotate on the top end of the supporting rod 804.

In this embodiment, the bottom of the connection plate 801 is attached to the top of the pressing plate 10, and in operation, the connection plate 801 can be separated from the pressing plate 10.

In the embodiment, the bottom of the pressing block 9 corresponds to the shaping section 6, and when in operation, the pressing block 9 is convenient to move to press the sintered porous bricks in the shaping section 6 in the shaping process.

The working principle of the device is as follows: when the device is used, firstly, the bottom of the base 1 of the device is placed on the flat ground, and after being placed firmly, raw materials are placed in a shaping zone 6 formed between a die carrier 5 inside a shaping box 3 and the inside of a placing groove 4, holes for sintering porous bricks are formed through fixing rods 7, then in the sintering process, a pressing plate 10 is driven by a lifting component 8 and a pressing block 9 to press the sintered porous bricks inside the shaping zone 6, and after the sintering is finished, the die carrier 5 is convenient to remove and demould through a jacking component 2, so that the device is convenient for the die carrier 5 of the sintered porous bricks inside the shaping box 3 to jack up and demould after the shaping through the jacking component 2 during the use, so that the device is convenient for carrying out quick demoulding treatment on the sintered porous bricks after the shaping, and avoiding the artificial demoulding from easily causing the breakage of the sintered porous bricks, avoiding influencing the normal processing effect of workers, avoiding unnecessary loss, and ensuring that the device is convenient to use and has strong practicability.

Of course, the above description is not intended to limit the utility model, but rather the utility model is not limited to the above examples, and variations, modifications, additions or substitutions within the spirit and scope of the utility model will be within the scope of the utility model.

Claims (6)

1. The utility model provides a high-efficient forming device of non-clay baked porous brick, includes base (1), its characterized in that: the base (1) is fixedly connected with a shaping box (3) at the center of the top, a holding groove (4) is formed in the shaping box (3), the upper surface of the inside of the holding groove (4) is communicated with the outside, a die carrier (5) is slidingly connected in the holding groove (4), a shaping interval (6) is formed between the die carrier (5) and the inside of the holding groove (4), a plurality of evenly distributed fixing rods (7) are fixedly connected at the corresponding part of the lower surface of the inside of the holding groove (4) and the shaping interval (6), the novel mold setting device is characterized in that a jacking component (2) is arranged inside the base (1), the jacking component (2) is installed with the mold frame (5), a lifting component (8) is arranged at the center of the rear surface of the setting box (3), a pressing plate (10) is arranged at the bottom of the lifting component (8), and a plurality of uniformly distributed pressing blocks (9) are fixedly connected to the bottom of the pressing plate (10).

2. The efficient non-clay sintered porous brick forming device according to claim 1, wherein: the jacking component (2) comprises a first inner groove (201) arranged at the inner center of the base (1), a third inner groove (218) is arranged at the center of the inner lower surface of the first inner groove (201), a first motor (217) is fixedly connected to the inner lower surface of the third inner groove (218), a second rotating rod (215) is fixedly connected to the output end of the first motor (217), a second slot (214) is arranged at the center of the inner upper surface of the first inner groove (201), the top end of the second rotating rod (215) is inserted into the second slot (214), and is rotationally connected with the slot II (214), a bevel gear IV (216) is fixedly connected below the outer surface of the rotating rod II (215), a bevel gear III (213) is meshed and connected on the left side and the right side of the bevel gear IV (216), a fixing plate (212) is fixedly connected on the left side and the right side of the inner part of the inner groove I (201), a left-right penetrating through hole (219) is formed in the inner center of the fixing plate (212), a rotating rod I (211) is rotationally connected in the through hole (219) through a bearing, one end of the rotating rod I (211) close to the inner center of the inner groove I (201) is fixedly connected with one side of the bevel gear III (213) away from the inner center of the inner groove I (201), one end of the first rotating rod (211) far away from the inner center of the first inner groove (201) is fixedly connected with a second bevel gear (210), the top of the second bevel gear (210) is in meshed connection with the first bevel gear (202), the left and right sides of the inner upper surface of the first inner groove (201) are provided with a first through groove (203) penetrating vertically, the left and right sides of the top of the base (1) are fixedly connected with support columns (205), the inner groove (206) is arranged in the support columns (205), the inner lower surface of the inner groove (206) is communicated with the inner part of the first through groove (203), the center of the inner upper surface of the inner groove (206) is provided with a first slot (208), the inner groove II (206) is internally provided with a left-right penetrating type through groove II (209) which is close to the upper part of the inner center of the base (1), the inside of the through groove II (209) is connected with a transverse plate (207) in a sliding manner, the corresponding part of the bottom of the transverse plate (207) and the top of the die carrier (5) is fixedly connected with a connecting block (221), the bottom of the connecting block (221) is fixedly connected with the top of the die carrier (5), the inside of the transverse plate (207) is positioned in the inner groove II (206) and is provided with a threaded hole (220) penetrating from top to bottom, the internal thread of the threaded hole (220) is connected with a threaded rod (204), the top of the threaded rod (204) is inserted into the slot I (208) and is rotationally connected with the slot I (208), and the bottom of the threaded rod (204) penetrates through the through groove I (203), is rotationally connected with the inside of the through groove I (203) through a bearing and is fixedly connected with the center of the top of the bevel gear I (202).

3. The efficient non-clay sintered porous brick forming device according to claim 1, wherein: lifting component (8) are including fixed connection bracing piece (804) of fixed box (3) rear surface center department, inside four (806) of inside top of bracing piece (804) have been seted up, just inside four (806) of inside upper surface communicates with each other with the outside, inside four (806) of inside lower surface fixedly connected with motor two (807), motor two (807) output fixedly connected with dwang three (808), the top of dwang three (808) runs through the top of bracing piece (804), and fixedly connected with backup pad (803), fixed surface is connected with connecting plate (801) before backup pad (803), up-and-down run through hole (805) have been seted up in connecting plate (801) inside the place ahead, connecting plate (801) top fixedly connected with electric lifter (802), electric lifter (802)'s output run through hole (805), and with the top fixedly connected with press clamp plate (10).

4. A non-clay sintered porous brick high efficiency molding apparatus according to claim 3, wherein: the top end of the supporting rod (804) is attached to the bottom of the supporting plate (803).

5. A non-clay sintered porous brick high efficiency molding apparatus according to claim 3, wherein: the bottom of the connecting plate (801) is attached to the top of the pressing plate (10).

6. The efficient non-clay sintered porous brick forming device according to claim 1, wherein: the bottom of the pressing block (9) corresponds to the shaping section (6).