CN111958764B - Die-casting forming device for soil bricks - Google Patents

Abstract

The invention relates to a die-casting forming device, in particular to a die-casting forming device for an earth brick. The invention aims to provide a die-casting forming device for an earth brick, which can automatically die-cast the earth brick. In order to solve the above-mentioned technical problems, the present invention provides a die-casting molding apparatus for an earth brick, comprising: the upper side of the bottom plate is connected with an operation box; the upper part in the operation box is connected with a baffle in a sliding way; the other side of the bottom plate is connected with a storage plate; the forming mechanism is arranged between the object placing plate and the operation box; and the switch mechanism is arranged on one side of the bottom plate close to the operation box and is in transmission connection with the forming mechanism. The baffle plate intermittently moves backwards and forwards to intermittently perform blanking so that soil falls on the pressing plate, the pressing plate moves upwards to be matched with the baffle plate so that the soil can be die-cast into bricks, and the push rod moves forwards so that the bricks on the pressing plate can be pushed out of the operation box.

Description

Die-casting forming device for soil bricks

Technical Field

The invention relates to a die-casting forming device, in particular to a die-casting forming device for an earth brick.

Background

At present, it is generally manual operation to die-cast earth brick with earth, in artifical pours earth into the earth brick mould into, then artifical manual messenger clamp plate reciprocates repeatedly and carries out the die-casting to earth, die-cast into massive earth brick with loose earth, so the workman need make great strength just can die-cast into massive earth brick with loose earth, workman's intensity of labour is big, and die-casting fashioned efficiency is slower, and rely on artifical power to die-cast loose earth completely, the earth brick that the die-casting was come out is not durable enough, thereby the earth brick easily spalls.

Therefore, it is necessary to develop a die-casting apparatus for bricks, which can automatically die-cast bricks.

Disclosure of Invention

(1) Technical problem to be solved

The invention aims to overcome the defect that loose soil needs to be manually and manually cast into a block-shaped soil brick by using a pressing plate, and the technical problem to be solved by the invention is to provide a casting and forming device for the soil brick, which can automatically cast the soil brick.

(2) Technical scheme

In order to solve the above-mentioned technical problems, the present invention provides a die-casting molding apparatus for an earth brick, comprising: the upper side of the bottom plate is connected with an operation box; the upper part in the operation box is connected with a baffle in a sliding way; the other side of the bottom plate is connected with a storage plate; the forming mechanism is arranged between the object placing plate and the operation box; and the switch mechanism is arranged on one side of the bottom plate close to the operation box and is in transmission connection with the forming mechanism.

Preferably, the molding mechanism includes: the servo motor is arranged on the object placing plate; one side of the operating box is rotatably connected with a rotating rod; a toothed chain transmission set is connected between the rotating rod and the servo motor; one side of the bottom plate close to the object placing plate is connected with a first fixed guide sleeve; the first fixed guide sleeve is rotatably connected with a first gear which is meshed with teeth on the chain transmission set with teeth; the connecting shaft of the first gear is connected with a crank connecting rod; the crank connecting rod is provided with a first transmission plate in a sliding manner; the first connecting plate is connected to the first transmission plate; the first connecting plate is connected with a first transmission plate which is positioned in the operating box; the second transmission plate is connected with the push plate; the inner walls of two sides of the operation box are connected with supporting blocks; the pressing plates are arranged between the supporting blocks.

Preferably, the switching mechanism comprises: one side of the bottom plate, which is close to the operation box, is connected with a loop bar; the telescopic rod is connected with the sleeve rod in a sliding manner; the bearing spring is connected between the telescopic rod and the sleeve rod; the telescopic rod is connected with the switch plate, and the switch plate is connected to the operation box in a sliding manner; one side of the switch plate is connected with the L-shaped connecting rod; the wedge block is connected to one side of the second transmission plate in a sliding mode and matched with the L-shaped connecting rod; and the supporting spring is connected between the wedge block and the second transmission plate.

Preferably, still include unloading mechanism, unloading mechanism includes: the transmission rod is rotatably connected to one side, close to the rotating rod, of the operating box; the end part of the transmission rod is connected with a second gear which is meshed with teeth on the transmission set of the chain with teeth; the transmission rod is connected with the half gear; the baffle is connected with a rack frame, and the rack frame is meshed with the half gear.

Preferably, the device further comprises an ejection mechanism, wherein the ejection mechanism comprises: the other side of the switch plate is connected with the first rack plate; the other side of the operating box is rotatably connected with a third gear, and the third gear is meshed with the first rack plate; the side, far away from the third gear, of the operating box is rotatably connected with a fourth gear; a belt transmission set is connected between the fourth gear and the third gear; the other side of the bottom plate, which is close to the operation box, is connected with a second fixed guide sleeve; the push rod is connected with the second fixed guide sleeve in a sliding mode and penetrates through the operating box; the push rod is connected with a second connecting plate; and the second rack plate is connected to the second connecting plate and meshed with the fourth gear.

(3) Advantageous effects

The baffle plate intermittently moves backwards and forwards to intermittently perform blanking so that soil falls on the pressure plate, the pressure plate moves upwards to be matched with the baffle plate to press and cast the soil into the soil bricks, and the push rod moves forwards to push the soil bricks on the pressure plate out of the operation box.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of the forming mechanism of the present invention.

Fig. 3 is a partial perspective view of the present invention.

Fig. 4 is a schematic perspective view of a second embodiment of the present invention.

The labels in the figures are: 1-a bottom plate, 2-an operation box, 21-a baffle, 3-a storage plate, 4-a forming mechanism, 41-a servo motor, 42-a toothed chain transmission set, 43-a first fixed guide sleeve, 44-a first gear, 45-a crank connecting rod, 46-a first transmission plate, 47-a first connecting plate, 48-a second transmission plate, 49-a push plate, 410-a press plate, 411-a supporting block, 5-a blanking mechanism, 51-a transmission rod, 52-a second gear, 53-a half gear, 54-a rack frame, 6-a switching mechanism, 61-a sleeve rod, 62-a bearing spring, 63-a telescopic rod, 64-a switching plate, 65-an L-shaped connecting rod, 66-a supporting spring, 67-a wedge block and 7-a pushing-out mechanism, 71-first rack plate, 72-third gear, 73-belt transmission group, 74-fourth gear, 75-second fixed guide sleeve, 76-second rack plate, 77-second connecting plate, 78-push rod.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

The utility model provides a die-casting forming device for earthenware brick, as shown in fig. 1-4, including bottom plate 1, control box 2, baffle 21, put thing board 3, forming mechanism 4 and on-off mechanism 6, the left side at bottom plate 1 top is connected with control box 2, upper portion slidingtype is connected with baffle 21 in the control box 2, 1 top right side of bottom plate is connected with puts thing board 3, install forming mechanism 4 between thing board 3 and the control box 2, on-off mechanism 6 is installed at 1 top of bottom plate of 2 front sides of control box, on-off mechanism 6 is connected with forming mechanism 4 transmission.

The forming mechanism 4 comprises a servo motor 41, a toothed chain transmission group 42, a first fixed guide sleeve 43, a first gear 44, a crank connecting rod 45, a first transmission plate 46, a first connecting plate 47, a second transmission plate 48, a push plate 49, a press plate 410 and a supporting block 411, wherein the servo motor 41 is installed at the top of the object placing plate 3, a rotating rod is rotatably connected to the right side surface of the operation box 2, the toothed chain transmission group 42 is connected between the rotating rod and an output shaft of the servo motor 41, the first fixed guide sleeve 43 is connected to the top of the bottom plate 1 at the left side of the object placing plate 3, the first gear 44 is rotatably connected to the first fixed guide sleeve 43, the first gear 44 is meshed with teeth on the toothed chain transmission group 42, the crank connecting rod 45 is connected to a connecting shaft of the first gear 44, the first transmission plate 46 is slidably arranged on the outer wall of the crank connecting rod 45, the first connecting plate 47 is connected to the left side surface of the first transmission plate 46, the second transmission plate 48 is connected to the left side surface of the first connecting plate 47, second driving plate 48 is located control box 2, and second driving plate 48 top is connected with push pedal 49, and baffle 21 below control box 2's front side inner wall and rear side inner wall all are connected with supporting block 411, have placed clamp plate 410 between the top of two supporting block 411, and clamp plate 410 is located push pedal 49 upside.

Switch mechanism 6 is including loop bar 61, bearing spring 62, telescopic link 63, switch plate 64, L shape connecting rod 65, supporting spring 66 and wedge 67, 1 top of bottom plate of control box 2 front side is connected with loop bar 61, sliding connection has telescopic link 63 in the loop bar 61, be connected with bearing spring 62 between the bottom in telescopic link 63 bottom and the loop bar 61, telescopic link 63 top is connected with switch plate 64, switch plate 64 sliding connection is on control box 2, switch plate 64 right flank is connected with L shape connecting rod 65, the right side sliding connection of second driving plate 48 has wedge 67, wedge 67 and the cooperation of L shape connecting rod 65, be connected with supporting spring 66 between wedge 67 and the right flank of second driving plate 48.

When the work of die-casting soil brick, can use this device, at first pour a large amount of loose earth into control box 2 in, baffle 21 can keep off earth, prevents that earth from falling by oneself. Then the baffle 21 is manually moved backwards, loose soil on the upper part of the operation box 2 falls on the pressing plate 410, and when a proper amount of soil falls on the pressing plate 410, the baffle 21 is manually moved forwards, so that the baffle 21 is reset to block the soil again. Initially, the second transmission plate 48 is located at the lower portion of the inside of the operation box 2, the servo motor 41 is manually actuated to rotate the toothed chain transmission set 42, the toothed chain transmission set 42 is rotated to rotate the first gear 44 via the teeth thereon, and the first gear 44 is rotated to move the first connection plate 47 up and down via the crank link 45 and the first transmission plate 46. When the teeth of the toothed chain drive set 42 rotate out of engagement with the first gear 44, the first gear 44 stops rotating, so that the first link plate 47 can intermittently move up and down. The first connecting plate 47 moves upwards to push the second transmission plate 48 to move upwards, the second transmission plate 48 moves upwards to enable the pressing plate 410 to move upwards through the pushing plate 49, the pressing plate 410 moves upwards to push soil on the pressing plate to move upwards, and the pressing plate 410 moves upwards to be matched with the baffle plate 21 to die-cast the soil into bricks. When the soil is cast into the soil brick, the first connecting plate 47 starts to move downwards to be reset, so that the push plate 49 moves downwards to be reset along with the downward movement, and the press plate 410 moves downwards to be reset under the action of gravity. The second transmission plate 48 moves downwards to enable the L-shaped connecting rod 65 to move downwards through the wedge-shaped block 67, the L-shaped connecting rod 65 moves downwards to drive the switch plate 64 to move downwards, the switch plate 64 moves downwards to drive the telescopic rod 63 to move downwards, and the bearing spring 62 is compressed accordingly; when the switch plate 64 is moved downward, a hand is manually inserted into the operation box 2 to take out the bricks on the pressing plate 410. When the wedge block 67 moves to be not contacted with the L-shaped connecting rod 65, the switch plate 64 can move upwards and reset under the action of the bearing spring 62; by repeating the above operations, the work of the die-casting bricks can be repeated, and after the work of the die-casting bricks is completed, the servo motor 41 is turned off.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and fig. 3 to 4, the blanking device further includes a blanking mechanism 5, the blanking mechanism 5 includes a transmission rod 51, a second gear 52, a half gear 53 and a rack frame 54, the transmission rod 51 is rotatably connected to the right side surface of the operation box 2 on the upper side of the transmission rod, the second gear 52 is connected to the right end of the transmission rod 51, the second gear 52 is engaged with the teeth on the toothed chain transmission set 42, the half gear 53 is connected to the transmission rod 51, the rack frame 54 is connected to the right side surface of the baffle 21, and the rack frame 54 is engaged with the half gear 53.

When the teeth on the toothed chain transmission set 42 rotate to be meshed with the second gear 52, the toothed chain transmission set 42 rotates to enable the second gear 52 to rotate, the second gear 52 rotates to drive the transmission rod 51 to rotate, the transmission rod 51 rotates to enable the rack frame 54 to move backwards and forwards through the half gear 53, and the rack frame 54 moves backwards and forwards to enable the baffle plate 21 to move backwards and forwards, so that manual operation is not needed to move the baffle plate 21 backwards and forwards. When the baffle 21 moves forwards and returns, the teeth on the toothed chain transmission set 42 rotate to be not meshed with the second gear 52, so that the baffle 21 can move backwards and forwards intermittently.

Example 3

In addition to embodiment 2, as shown in fig. 1, 3 and 4, the push-out device 7 further includes a push-out mechanism 7, the push-out mechanism 7 includes a first rack plate 71, a third gear 72, a belt transmission set 73, a fourth gear 74, a second fixed guide 75, a second rack plate 76, a second connecting plate 77 and a push rod 78, the first rack plate 71 is connected to the left side of the switch plate 64, the third gear 72 is rotatably connected to the left side of the operation box 2, the third gear 72 is meshed with the first rack plate 71, the fourth gear 74 is rotatably connected to the left side of the operation box 2 above the third gear 72, the belt transmission set 73 is connected between the fourth gear 74 and the third gear 72, the second fixed guide 75 is connected to the bottom plate 1 at the rear side of the operation box 2, the push rod 78 is slidably connected in the second fixed guide 75, the push rod 78 passes through the rear side of the operation box 2, the second connecting plate 77 is connected to the rear side of the left side of the push rod 78, a second rack plate 76 is attached to the front side surface of the second connecting plate 77, and the second rack plate 76 is engaged with the fourth gear 74.

The switch plate 64 moves downwards to drive the first rack plate 71 to move downwards, the first rack plate 71 moves downwards to enable the third gear 72 to rotate clockwise, the third gear 72 rotates clockwise to enable the fourth gear 74 to rotate clockwise through the belt transmission set 73, the fourth gear 74 rotates clockwise to enable the second rack plate 76 to move forwards, the second rack plate 76 moves forwards to enable the push rod 78 to move forwards through the second connecting plate 77, the push rod 78 moves forwards to enable the soil bricks on the pressing plate 410 to be pushed out of the operation box 2, and therefore hands do not need to be manually stretched into the operation box 2 to take out the soil bricks on the pressing plate 410. When the switch plate 64 is moved upward to reset, the push rod 78 can be moved backward to reset.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, various changes, modifications and substitutions can be made without departing from the spirit of the present invention, and these are all within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (4)

1. A die-casting forming device for an earthen brick is characterized by comprising:

the device comprises a bottom plate (1), an operation box (2) connected with one side of the bottom plate;

the baffle (21) is connected to the upper part in the operating box (2) in a sliding manner;

the other side of the bottom plate (1) is connected with the object placing plate (3);

the forming mechanism (4) is arranged between the storage plate (3) and the operation box (2);

the switch mechanism (6) is arranged on one side, close to the operation box (2), of the bottom plate (1), and the switch mechanism (6) is in transmission connection with the forming mechanism (4);

the molding mechanism (4) includes:

the servo motor (41), install the servo motor (41) on the shelf board (3);

one side of the operating box (2) is rotatably connected with a rotating rod;

a toothed chain transmission group (42), wherein a toothed chain transmission group (42) is connected between the rotating rod and the servo motor (41);

the side, close to the object placing plate (3), of the bottom plate (1) is connected with a first fixed guide sleeve (43);

the first gear (44) is rotationally connected to the first fixing guide sleeve (43), and the first gear (44) is meshed with teeth on the toothed chain transmission set (42);

the connecting shaft of the first gear (44) is connected with a crank connecting rod (45);

the first transmission plate (46) is arranged on the crank connecting rod (45) in a sliding mode;

a first connecting plate (47), the first connecting plate (47) being connected to the first transmission plate (46);

the first connecting plate (47) is connected with a second transmission plate (48), and the second transmission plate (48) is positioned in the operating box (2);

the second transmission plate (48) is connected with the push plate (49);

the inner walls of two sides of the operating box (2) are connected with supporting blocks (411);

the pressing plates (410) are placed between the pressing plates (410) and the supporting blocks (411).

2. The die-casting molding apparatus for an earthen brick as claimed in claim 1, wherein the switch mechanism (6) comprises:

the sleeve rod (61) is connected to one side, close to the operating box (2), of the bottom plate (1);

the telescopic rod (63) is connected with the loop bar (61) in a sliding way;

the bearing spring (62) is connected between the telescopic rod (63) and the sleeve rod (61);

the switch plate (64) is connected to the telescopic rod (63), and the switch plate (64) is connected to the operation box (2) in a sliding mode;

one side of the switch plate (64) is connected with the L-shaped connecting rod (65);

the wedge block (67) is connected to one side of the second transmission plate (48) in a sliding mode, and the wedge block (67) is matched with the L-shaped connecting rod (65);

and a support spring (66) is connected between the wedge block (67) and the second transmission plate (48).

3. The die-casting molding device for the earth brick as claimed in claim 2, further comprising a blanking mechanism (5), wherein the blanking mechanism (5) comprises:

the transmission rod (51) is rotatably connected to one side, close to the rotating rod, of the operating box (2);

the end part of the transmission rod (51) is connected with a second gear (52), and the second gear (52) is meshed with teeth on the toothed chain transmission group (42);

the transmission rod (51) is connected with the half gear (53);

the baffle plate (21) is connected with a rack frame (54), and the rack frame (54) is meshed with the half gear (53).

4. The die-casting molding device for an earthen brick as claimed in claim 3, further comprising an ejecting mechanism (7), wherein the ejecting mechanism (7) comprises:

the other side of the switch plate (64) is connected with the first rack plate (71);

the other side of the operating box (2) is rotatably connected with a third gear (72), and the third gear (72) is meshed with the first rack plate (71);

a fourth gear (74), wherein the side of the operating box (2) far away from the third gear (72) is rotatably connected with the fourth gear (74);

the belt transmission group (73) is connected between the fourth gear (74) and the third gear (72);

the other side, close to the operation box (2), of the bottom plate (1) is connected with a second fixed guide sleeve (75);

the push rod (78) is connected with the second fixing guide sleeve (75) in a sliding mode, and the push rod (78) penetrates through the operation box (2);

the push rod (78) is connected with the second connecting plate (77);

the second rack plate (76) is connected to the second connecting plate (77), and the second rack plate (76) is meshed with the fourth gear (74).

Images