JP2021084013A - Rice chest in which rice is easy to store and which can be used for classifying rice - Google Patents

Abstract

To disclose a rice chest in which rice is easy to store and which can be used for classifying rice.SOLUTION: A rice chest in which rice is easy to store and which can be used for classifying rice comprises a rice chest. In the rice chest, a storage space opening upward is provided. In the rice chest, a rice input mechanism to which rice can be input automatically is provided. The rice input mechanism includes a lid plate that is positioned above the rice chest and is capable of shielding the storage space. At a left end of the lid plate, a hinge whose lower end is fixedly connected to the rice chest is fixed. In the rice chest, an annular space that opens upward and takes the storage space as its center is provided. In the annular space, an annular disturbance plate having an upper end abutting on the lid plate is provided. In the annular space, two support springs supporting the annular disturbance plate are further provided. On each of left and right walls of the storage space, a position restriction space is provided so as to communicate with the storage space.SELECTED DRAWING: Figure 1

Description

The present invention deals with the field of storage, and particularly relates to a rice bowl that is easy to put rice in and can be divided.

A rice bowl is a container that holds rice for cooking rice. Materials include wood (paulownia), plastic, and stainless steel. To put rice in a rice bowl, the rice bag is mainly broken manually, and then the rice bag is tilted to put the rice in the rice bowl, which consumes time and labor and is inefficient. Also, if rice is put in manually, the rice bag is too heavy and there is a risk of spilling the rice. Furthermore, since there are various types of rice, if different rice is put into one rice bowl without discrimination, the texture of cooked rice will be affected.

Chinese Patent Application Publication No. 104528188

By providing a rice bowl that is easy to put in rice and can separate rice, the time and effort spent to put in rice can be reduced, and two types of rice can be separated.

The present invention is realized by the following technical solutions.

The rice bowl described in the present application, which is easy to put rice in and can separate rice, includes a rice bowl, a storage space opening upward is provided in the rice bowl, and rice is automatically placed in the rice bowl. A rice-filling mechanism is provided, and the rice-filling mechanism includes a lid plate that is located above the rice bowl and can block the storage space, and the lower end of the lid plate is fixed to the rice bowl at the left end. A hinge connected to the above is fixed, an annular space is provided in the rice bowl, which opens upward and is centered on the storage space, and an annular space in which the upper end abuts on the lid plate. An obstruction plate is provided, and two support springs for supporting the annular obstruction plate are further provided in the annular space, and position limiting spaces communicate with the storage space on the left and right walls of the storage space. Support rods are provided in the storage space, and the left and right ends of the support rods are located in the position-restricted space on the left and the position-restricted space on the right, respectively, and below the position-restricted space. A compression spring whose upper end is fixedly connected to the support rod is fixed to the wall, a sliding space is provided in the support rod, and the upper wall of the sliding space is the storage space and the position limitation. It communicates with the space, a sliding spring is fixedly connected to the right wall of the sliding space, a slider is fixedly connected to the left end of the sliding spring, and an upper end is fixedly connected to the upper end of the slider. The blade located in the position-restricted space on the left is fixed, a holding space is provided in the left wall of the position-restricted space on the left, and two holding blocks are provided in the holding space. The lower end of the holding block is fixedly connected to the lower wall of the holding space, the upper holding spring is fixed to the upper end of the holding spring, and the upper end of the holding spring is fixedly connected to the upper wall of the holding space. The upper holding block is connected to the upper end of the holding rope, and the upper end of the connecting rope penetrates the upper wall of the holding space and the upper wall of the right position limiting space and is fixed to the support rod. A tow rope is fixedly connected to the left lower end of the annular obstruction plate, and the lower end of the tow rope is the lower wall of the annular space, the left and right walls of the holding space, and the left of the sliding space. It penetrates the wall and is fixedly connected to the slider. In the holding space, the tow rope is held by two holding blocks, and the storage space is divided into two spaces in the storage space. A mechanism is provided, and an auxiliary mechanism is provided on the lower wall of the annular space, and the auxiliary mechanism can more easily discharge rice from the storage space by mixing rice, and the storage space below the division mechanism. A rice discharge mechanism that can discharge rice is provided in the space, and the rice filling mechanism automatically puts rice from the rice bag into the rice bowl, avoiding spills of rice and saving time and labor. By the split mechanism and the rice discharge mechanism, new rice and old rice can be separated and mixed can be avoided.

Further, the dividing mechanism includes a dividing plate fixed in the storage space and dividing the storage space, and a penetrating space penetrating the upper and lower surfaces of the dividing plate is provided in the dividing plate. A sensor is fixedly provided in the left wall of the through space, an extrusion groove that opens downward is formed in each of the left and right walls of the penetration space, and the lower end is stored in the extrusion groove. A connecting block located in the space is provided, a tension spring for connecting the connecting block and the upper wall of the extrusion groove is further provided in the extrusion groove, and a position limiting groove is provided in the connecting block. Is formed, and the wall away from the penetrating space in the position limiting groove communicates with the storage space, and is fixedly connected to the lower end of the connecting block in the storage space and closes the penetrating space. A limit plate that can be provided is provided, and the extrusion space is provided in the wall away from the through space in the extrusion groove so that the extrusion space communicates with the extrusion groove, and one end of the extrusion space is provided in the extrusion groove. A trapezoidal block is provided, and an extrusion spring for repositioning the trapezoidal block is further provided in the extrusion space.

Further, the auxiliary mechanism includes an annular rotation space, and an annular sealing space is provided between the annular rotation space and the storage space. In the annular sealing space, the outer wall communicates with the annular rotation space, whereas the inner wall thereof. Is communicated with the storage space, an annular sealing plate is slidably connected in the annular sealing space, and an annular rotating gear is slidably connected in the annular rotating space, and the annular is slidably connected. Two connecting rods are fixedly connected to the inner wall of the rotating gear, and one end of the two connecting rods penetrates the annular sealing space and the annular sealing plate and extends to the storage space. A rotation motor is fixedly connected to the upper wall of the annular rotation space, a rotation shaft is movably connected to the lower end of the rotation motor, and the left end is an annular shape to the lower end of the rotation shaft. The rotating gear that meshes with the right end of the rotating gear is fixed.

Further, the rice discharge mechanism includes a discharge space that communicates the storage space with the outside, an electromagnetic switch that can be operated intermittently is provided in the discharge space, and an annular support plate is provided in the storage space. Two spring grooves that open upward are formed in the lower wall of the storage space, and a spring block whose upper end is fixedly connected to the annular support plate is provided in the spring groove. A telescopic spring for supporting the spring block is further provided in the spring groove, a chain and a rope are fixedly connected to the lower end of the spring block, and the upper end is an annular support in the discharge space. An annular tub fixedly connected to the plate is provided, two triangular plates are provided above the annular support plate, an elevating groove is formed in the triangular plate, and one wall of the elevating groove is preserved. An elevating block that communicates with the space and can be elevated is provided in the elevating groove, and one end of the connecting rod penetrates the wall of the elevating groove and is fixedly connected to the elevating block. An alarm controlled by the sensor is fixed to the right side of the rod, a push switch capable of controlling the operation of the electromagnetic switch is fixedly connected to the right side of the rice rod, and the lower end of the rope is the spring groove. The lower wall is fixedly connected to the connecting block through the lower wall and the upper wall of the extrusion groove, and the lower end of the chain penetrates the lower wall of the spring groove and the wall of the extrusion space to form the trapezoidal block. Is fixedly connected to.

Further, the elasticity of the support spring is weaker than the gravity of the lid plate, the elasticity of the sliding spring is weaker than the frictional force between the two holding blocks and the tow rope, and the elasticity of the tension spring is the extrusion spring. The elasticity of the telescopic spring is stronger than the elasticity of the extrusion spring.

The present invention has the following positive effects: The present invention automatically breaks the rice bag placed in the rice bowl, and the rice can fall into the rice bowl by its own weight, that is, it is convenient to put the rice in, and the rice may spill. In addition, if there is old rice in the rice bowl and new rice is added, the present invention automatically separates the two types of rice and avoids mixing.

In order to explain the present invention in detail and conveniently explain the present invention together with FIGS. 1 to 3 below, each direction described in the present application is defined as follows: FIG. 1 is a front view of the present invention and is described in the present application. Each of the described directions is based on the observation direction in FIG.

FIG. 1 is a schematic configuration of the present invention. FIG. 2 is an enlarged front view of part A in FIG. FIG. 3 is an enlarged front view of part B in FIG.

The rice bowl described in the present application in which rice can be easily put in and the rice can be separated includes a rice bowl 10, and a storage space 12 that opens upward is provided in the rice bowl 10, and the rice bowl 10 contains a storage space 12 that opens upward. A rice-filling mechanism 61 for automatically inserting rice is provided, and the rice-filling mechanism 61 includes a lid plate 38 located above the rice bowl 10 and capable of blocking the storage space 12, and is the left end of the lid plate 38. A hinge 37 whose lower end is fixedly connected to the rice bowl 10 is fixed to the rice bowl 10, and an annular space 13 having an opening upward and centered on the storage space 12 is provided in the rice bowl 10. An annular interfering plate 11 whose upper end abuts on the lid plate 38 is provided in the annular space 13, and two support springs 14 for supporting the annular interfering plate 11 are further provided in the annular space 13. A position limiting space 48 is provided on the left and right walls of the storage space 12 so as to communicate with the storage space 12, and a support rod 46 is provided in the storage space 12, and the support rod 46 is provided. The left and right ends are located in the position limiting space 48 on the left and the position limiting space 48 on the right, respectively, and a compression spring 47 whose upper end is fixedly connected to the support rod 46 is attached to the lower wall of the position limiting space 48. It is fixed, a sliding space 43 is provided in the support rod 46, and the upper wall of the sliding space 43 communicates the storage space 12 and the position limiting space 48, and the sliding space 43. A sliding spring 44 is fixedly connected to the right wall of the sliding spring 44, a slider 45 is fixedly connected to the left end of the sliding spring 44, and the upper end of the slider 45 is fixedly connected to the position limiting space 48 whose upper end is left. The blade 42 located in is fixed, a holding space 39 is provided in the left wall of the position limiting space 48 on the left, and two holding blocks 49 are provided in the holding space 39. The lower end of the holding block 49 is fixedly connected to the lower wall of the holding space 39, the holding spring 41 is fixed to the upper end of the upper holding block 49, and the upper end of the holding spring 41 is the upper wall of the holding space 39. The connecting rope 40 is fixed to the upper end of the holding block 49 above, and the upper end of the connecting rope 40 connects the upper wall of the holding space 39 and the upper wall of the position limiting space 48 on the right. It penetrates and is fixedly connected to the support rod 46, a tow rope 36 is fixedly connected to the left lower end of the annular interfering plate 11, and the lower end of the tow rope 36 is connected to the lower wall of the annular space 13. The left and right walls of the holding space 39 and the left wall of the sliding space 43 are pierced and fixedly connected to the slider 45, and the front in the holding space 39. The tow rope 36 is sandwiched by the two sandwiching blocks 49, and a dividing mechanism 60 for dividing the storage space 12 into two spaces is provided in the storage space 12, and the lower wall of the annular space 13 is provided with a dividing mechanism 60. An auxiliary mechanism 62 is provided, and the auxiliary mechanism 62 can more easily discharge rice from the storage space 12 by mixing rice, and can discharge rice into the storage space 12 below the division mechanism 60. The rice discharge mechanism 63 is provided, and the rice filling mechanism 61 automatically puts rice from the rice bag into the rice bowl 10, so that rice spills can be avoided and time and labor can be saved. With the rice discharge mechanism 63, new rice and old rice can be separated and mixed can be avoided.

Advantageously, the dividing mechanism 60 includes a dividing plate 52 fixed in the storage space 12 and dividing the storage space 12, and the upper and lower surfaces of the dividing plate 52 are contained in the dividing plate 52. A penetrating space 55 is provided, a sensor 56 is fixedly provided in the left wall of the penetrating space 55, and an extrusion groove 53 that opens downward is provided in each of the left and right walls of the penetrating space 55. A connecting block 57 having a lower end located in the storage space 12 is provided in the extrusion groove 53, and the connecting block 57 and the upper wall of the extrusion groove 53 are further provided in the extrusion groove 53. A tension spring 54 is provided, and a position limiting groove 59 is formed in the connecting block 57, and a wall away from the through space 55 in the position limiting groove 59 communicates with the storage space 12. A limiting plate 58 that is fixedly connected to the lower end of the connecting block 57 and can close the penetrating space 55 is provided in the storage space 12, and a wall away from the penetrating space 55 in the extrusion groove 53. The extrusion space 65 is provided in the extrusion space 65 so as to communicate with the extrusion groove 53, and a trapezoidal block 51 having one end located in the extrusion groove 53 is provided in the extrusion space 65. Further, an extrusion spring 50 for repositioning the trapezoidal block 51 is provided inside.

Advantageously, the auxiliary mechanism 62 includes an annular rotation space 33, an annular sealing space 31 is provided between the annular rotation space 33 and the storage space 12, and the outer wall of the annular sealing space 31 has an annular shape. The inner wall communicates with the storage space 12 while communicating with the rotating space 33, and the annular sealing plate 35 is slidably connected in the annular sealing space 31 and into the annular rotating space 33. In, the annular rotating gear 34 is slidably connected, two connecting rods 32 are fixedly connected to the inner wall of the annular rotating gear 34, and one end of the two connecting rods 32 is the annular sealing space 31. The rotating motor 15 is fixedly connected to the upper wall of the annular rotating space 33, and extends to the storage space 12 through the annular sealing plate 35 and the lower end of the rotating motor 15. A rotating shaft 17 is movably connected to the space, and a rotating gear 19 whose left end meshes with the right end of the annular rotating gear 34 is fixed to the lower end of the rotating shaft 17.

Advantageously, the rice discharge mechanism 63 includes a discharge space 25 that communicates the storage space 12 with the outside, and an electromagnetic switch 26 that can be operated intermittently is provided in the discharge space 25. An annular support plate 64 is provided in the storage space 12, two spring grooves 22 that open upward are formed in the lower wall of the storage space 12, and the upper end of the spring groove 22 supports the annular support. A spring block 21 fixedly connected to the plate 64 is provided, a telescopic spring 28 for supporting the spring block 21 is further provided in the spring groove 22, and a chain 27 and a rope are provided at the lower end of the spring block 21. An annular tub 24 whose upper end is fixedly connected to the annular support plate 64 is provided in the discharge space 25 which is fixedly connected to the 23, and a triangular plate 30 is provided above the annular support plate 64. Two elevating grooves 20 are provided in the triangular plate 30, one wall of the elevating groove 20 communicates with the storage space 12, and an elevating block that can be raised and lowered in the elevating groove 20. 29 is provided, one end of the connecting rod 32 penetrates the wall of the elevating groove 20 and is fixedly connected to the elevating block 29, and an alarm device controlled by the sensor 56 is provided on the right surface of the rice paddle 10. 16 is fixed, and a push switch 18 capable of controlling the operation of the electromagnetic switch 26 is fixedly connected to the right surface of the rice paddle 10, and the lower end of the rope 23 is the lower wall of the spring groove 22 and the extrusion groove. It penetrates the upper wall of 53 and is fixedly connected to the connecting block 57, and the lower end of the chain 27 penetrates the lower wall of the spring groove 22 and the wall of the extrusion space 65 to form the trapezoidal block 51. It is fixedly connected.

Advantageously, the elasticity of the support spring 14 is weaker than the gravity of the lid plate 38, and the elasticity of the sliding spring 44 is weaker than the frictional force between the two sandwiching blocks 49 and the tow rope 36. The elasticity of the tension spring 54 is stronger than the elasticity of the extrusion spring 50, and the elasticity of the telescopic spring 28 is stronger than the elasticity of the extrusion spring 50.

First, the tension spring 54 and the sliding spring 44 are in a tension state, the support spring 14 and the expansion spring 28 are in a compression state, and the storage space 12 is packed with rice.

To take rice in a fixed amount, press the push switch 18 to activate the electromagnetic switch 26, and then the rice leaves the storage space 12 and the discharge space 25, and after a certain period of time, the electromagnetic switch 26 automatically operates. The operation is stopped, the discharge space 25 is closed, and the rotation motor 15 is operated by the operation of the electromagnetic switch 26 to drive and rotate the rotation shaft 17 and the rotation gear 19, and then the annular rotation gear 34. And the connecting rod 32 rotate in conjunction with each other, and by rotating the annular sealing plate 35 and the elevating block 29, the triangular plate 30 rotates above the annular support plate 64 and moves the rice deposited in the storage space 12. , The rice is not blocked when it is discharged.

When there is no rice in the penetrating space 55, the sensor 56 controls and activates the alarm device 16 to indicate to the user that there is a shortage of rice by the alarm device 16, and since there is no rice in the penetrating space 55, the tension spring 54 is By repositioning and raising the connecting block 57 and the limiting plate 58, the penetrating space 55 is closed by the limiting plate 58 and the storage spaces 12 above and below the dividing plate 52 are blocked so that they cannot communicate with each other, and the connecting block 57 rises. When the trapezoidal block 51 is returned to the extrusion space 65 and the extrusion spring 50 is compressed and the connecting block 57 is raised along the position limiting groove 59 to the same height as the extrusion space 65, the extrusion spring 50 is repositioned and the trapezoidal block The 51 is inserted into the position limiting groove 59 to limit the descent of the connecting block 57.

To put rice in the storage space 12, the lid plate 38 is manually circulated to communicate the storage space 12 with the outside, and then a rice bag filled with rice is placed above the support rod 46, and the lid plate 38 is a rice paddle. Since the support spring 14 is repositioned and raises the annular obstruction plate 11 because it is separated from the upper part of 10, the annular obstruction plate 11 is positioned outside, that is, the rice does not spill when the rice is discharged from the rice bag, and the annular obstruction plate 11 is discharged. When the tow rope 36 is loosened by the ascent of 11 and the rice bag is placed on the support rod 46, the support rod 46 is lowered and the position limiting space 48 is compressed, and the connecting rope 40 is pulled by the lowering of the support rod 46 and is moved up. The pinching block 49 is raised to compress the pinching spring 41, and the two pinching blocks 49 no longer pinch the tow rope 36. Here, the sliding spring 44 is repositioned and the slider 45 and the blade 42 are moved to the right. The upper end of the blade 42 cuts through the lower end of the rice bag, the rice enters above the dividing plate 52 from the cut end by its own weight, and when all the rice in the rice bag has fallen, the rice bag can be easily removed.

After stuffing the rice, push the annular obstruction plate 11 downward by hand, go around the lid plate 38, close the storage space 12 again by the lid plate 38, and the support spring 14 is restored and pulled by the lowering of the annular obstruction plate 11. The rope 36 is also pulled, and by removing the rice bag, the position limiting space 48 is repositioned with the support rod 46, and then the connecting rope 40 is loosened, and the pinching spring 41 is repositioned to lower the upper pinching block 49. Here, the holding block 49 holds the tow rope 36 again, and when the annular obstruction plate 11 descends and pulls the tow rope 36, the slider 45 and the blade 42 are interlocked to return to the left.

When the old rice below the dividing plate 52 is used up, the telescopic spring 28 is repositioned, and by interlocking the spring block 21, the annular support plate 64 and the annular tub 24 are raised, and then the triangular plate 30 is interlocked and raised. , The rise of the spring block 21 tightens the chain 27 and the rope 23, the chain 27 returns the trapezoidal block 51 to the extrusion space 65, the connecting block 57 is no longer restricted, and the gravity of the new rice in the through space 55 causes the limiting plate 58. And the connecting block 57 descends, the tension spring 54 is pulled again, the new rice goes from the upper side to the lower side of the split plate 52, and the annular support plate 64 and the spring block 21 are lowered again, so that the telescopic spring 28 is renewed. In the compressed state, the chain 27 and the rope 23 are loosened again, and the extrusion spring 50 repositions the trapezoidal block 51.

According to the above method, an engineer in the field can make various modifications according to the working situation within the scope of the present invention.

The present invention deals with the field of storage, and particularly relates to a rice bowl that is easy to put rice in and can be divided.

A rice bowl is a container that holds rice for cooking rice. Materials include wood (paulownia), plastic, and stainless steel. To put rice in a rice bowl, the rice bag is mainly broken manually, and then the rice bag is tilted to put the rice in the rice bowl, which consumes time and labor and is inefficient. Also, if rice is put in manually, the rice bag is too heavy and there is a risk of spilling the rice. Furthermore, since there are various types of rice, if different rice is put into one rice bowl without discrimination, the texture of cooked rice will be affected.

Chinese Patent Application Publication No. 104528188

By providing a rice bowl that is easy to put in rice and can separate rice, the time and effort spent to put in rice can be reduced, and two types of rice can be separated.

The present invention is realized by the following technical solutions.

The rice bowl described in the present application, which is easy to put rice in and can separate rice, includes a rice bowl, a storage space opening upward is provided in the rice bowl, and rice is automatically placed in the rice bowl. A rice-filling mechanism is provided, and the rice-filling mechanism includes a lid plate that is located above the rice bowl and can block the storage space, and the lower end of the lid plate is fixed to the rice bowl at the left end. A hinge connected to the above is fixed, an annular space is provided in the rice bowl, which opens upward and is centered on the storage space, and an annular space in which the upper end abuts on the lid plate. An obstruction plate is provided, and two support springs for supporting the annular obstruction plate are further provided in the annular space, and position limiting spaces communicate with the storage space on the left and right walls of the storage space. Support rods are provided in the storage space, and the left and right ends of the support rods are located in the position-restricted space on the left and the position-restricted space on the right, respectively, and below the position-restricted space. A compression spring whose upper end is fixedly connected to the support rod is fixed to the wall, a sliding space is provided in the support rod, and the upper wall of the sliding space is the storage space and the position limitation. It communicates with the space, a sliding spring is fixedly connected to the right wall of the sliding space, a slider is fixedly connected to the left end of the sliding spring, and an upper end is fixedly connected to the upper end of the slider. The blade located in the position-restricted space on the left is fixed, a holding space is provided in the left wall of the position-restricted space on the left, and two holding blocks are provided in the holding space. The lower end of the holding block is fixedly connected to the lower wall of the holding space, the upper holding spring is fixed to the upper end of the holding spring, and the upper end of the holding spring is fixedly connected to the upper wall of the holding space. The upper holding block is connected to the upper end of the holding rope, and the upper end of the connecting rope penetrates the upper wall of the holding space and the upper wall of the right position limiting space and is fixed to the support rod. is coupled to, wherein the lower left corner of the annular interference plate traction rope is fixedly coupled, the traction rope and the left and right walls of the front bellflower lifting space bottom, through the left wall of the sliding space It is fixedly connected to the slider, the tow rope is sandwiched by the two sandwiching blocks in the sandwiching space, and a dividing mechanism for dividing the storage space into two spaces is provided in the storage space, and the annular shape is provided. An auxiliary mechanism is provided on the lower wall of the space, and the auxiliary mechanism can more easily discharge rice from the storage space by mixing rice, and discharges rice into the storage space below the division mechanism. Can A rice discharging mechanism is provided, and the rice filling mechanism automatically puts rice from the rice bag into the rice bowl, avoiding spilling of rice and saving time and labor, and the dividing mechanism and the rice discharging mechanism. By doing so, new rice and old rice can be separated and mixed can be avoided.

Further, the dividing mechanism includes a dividing plate fixed in the storage space and dividing the storage space, and a penetrating space penetrating the upper and lower surfaces of the dividing plate is provided in the dividing plate. A sensor is fixedly provided in the left wall of the through space, an extrusion groove that opens downward is formed in each of the left and right walls of the penetration space, and the lower end is stored in the extrusion groove. A connecting block located in the space is provided, a tension spring for connecting the connecting block and the upper wall of the extrusion groove is further provided in the extrusion groove, and a position limiting groove is provided in the connecting block. Is formed, and the wall away from the penetrating space in the position limiting groove communicates with the storage space, and is fixedly connected to the lower end of the connecting block in the storage space and closes the penetrating space. A limit plate that can be provided is provided, and the extrusion space is provided in the wall away from the through space in the extrusion groove so that the extrusion space communicates with the extrusion groove, and one end of the extrusion space is provided in the extrusion groove. A trapezoidal block is provided, and an extrusion spring for repositioning the trapezoidal block is further provided in the extrusion space.

Further, the auxiliary mechanism includes an annular rotation space, and an annular sealing space is provided between the annular rotation space and the storage space. In the annular sealing space, the outer wall communicates with the annular rotation space, whereas the inner wall thereof. Is communicated with the storage space, an annular sealing plate is slidably connected in the annular sealing space, and an annular rotating gear is slidably connected in the annular rotating space, and the annular is slidably connected. Two connecting rods are fixedly connected to the inner wall of the rotating gear, and one end of the two connecting rods penetrates the annular sealing space and the annular sealing plate and extends to the storage space. A rotation motor is fixedly connected to the upper wall of the annular rotation space, a rotation shaft is movably connected to the lower end of the rotation motor, and the left end is an annular shape to the lower end of the rotation shaft. The rotating gear that meshes with the right end of the rotating gear is fixed.

Further, the rice discharge mechanism includes a discharge space that communicates the storage space with the outside, an electromagnetic switch that can be operated intermittently is provided in the discharge space, and an annular support plate is provided in the storage space. Two spring grooves that open upward are formed in the lower wall of the storage space, and a spring block whose upper end is fixedly connected to the annular support plate is provided in the spring groove. A telescopic spring for supporting the spring block is further provided in the spring groove, a chain and a rope are fixedly connected to the lower end of the spring block, and the upper end is an annular support in the discharge space. An annular tub fixedly connected to the plate is provided, two triangular plates are provided above the annular support plate, an elevating groove is formed in the triangular plate, and the through portion of the elevating groove is preserved. penetrates the end face of the triangular plate close to the inner wall of the space, liftable lifting block is provided in said elevating groove, one end of the connecting rod and the lifting block through the wall of the lifting groove It is fixedly connected, an alarm device controlled by the sensor is fixed to the right side of the rice bowl, and a push switch capable of controlling the operation of the electromagnetic switch is fixedly connected to the right side of the rice bowl. The lower end of the rope penetrates the lower wall of the spring groove and the upper wall of the extrusion groove and is fixedly connected to the connecting block, and the lower end of the chain is the lower wall of the spring groove and the wall of the extrusion space. It penetrates and is fixedly connected to the trapezoidal block.

Further, the elasticity of the support spring is weaker than the gravity of the lid plate, the elasticity of the sliding spring is weaker than the frictional force between the two holding blocks and the tow rope, and the elasticity of the tension spring is the extrusion spring. The elasticity of the telescopic spring is stronger than the elasticity of the extrusion spring.

The present invention has the following positive effects: The present invention automatically breaks the rice bag placed in the rice bowl, and the rice can fall into the rice bowl by its own weight, that is, it is convenient to put the rice in, and the rice may spill. In addition, if there is old rice in the rice bowl and new rice is added, the present invention automatically separates the two types of rice and avoids mixing.

In order to explain the present invention in detail and conveniently explain the present invention together with FIGS. 1 to 3 below, each direction described in the present application is defined as follows: FIG. 1 is a front view of the present invention and is described in the present application. Each of the described directions is based on the observation direction in FIG.

FIG. 1 is a schematic configuration of the present invention. FIG. 2 is an enlarged front view of part A in FIG. FIG. 3 is an enlarged front view of part B in FIG.

The rice bowl described in the present application in which rice can be easily put in and the rice can be separated includes a rice bowl 10, and a storage space 12 that opens upward is provided in the rice bowl 10, and the rice bowl 10 contains a storage space 12 that opens upward. A rice-filling mechanism 61 for automatically inserting rice is provided, and the rice-filling mechanism 61 includes a lid plate 38 located above the rice bowl 10 and capable of blocking the storage space 12, and is the left end of the lid plate 38. A hinge 37 whose lower end is fixedly connected to the rice bowl 10 is fixed to the rice bowl 10, and an annular space 13 having an opening upward and centered on the storage space 12 is provided in the rice bowl 10. An annular interfering plate 11 whose upper end abuts on the lid plate 38 is provided in the annular space 13, and two support springs 14 for supporting the annular interfering plate 11 are further provided in the annular space 13. A position limiting space 48 is provided on the left and right walls of the storage space 12 so as to communicate with the storage space 12, and a support rod 46 is provided in the storage space 12, and the support rod 46 is provided. The left and right ends are located in the position limiting space 48 on the left and the position limiting space 48 on the right, respectively, and a compression spring 47 whose upper end is fixedly connected to the support rod 46 is attached to the lower wall of the position limiting space 48. It is fixed, a sliding space 43 is provided in the support rod 46, and the upper wall of the sliding space 43 communicates the storage space 12 and the position limiting space 48, and the sliding space 43. A sliding spring 44 is fixedly connected to the right wall of the sliding spring 44, a slider 45 is fixedly connected to the left end of the sliding spring 44, and the upper end of the slider 45 is fixedly connected to the position limiting space 48 whose upper end is left. The blade 42 located in is fixed, a holding space 39 is provided in the left wall of the position limiting space 48 on the left, and two holding blocks 49 are provided in the holding space 39. The lower end of the holding block 49 is fixedly connected to the lower wall of the holding space 39, the holding spring 41 is fixed to the upper end of the upper holding block 49, and the upper end of the holding spring 41 is the upper wall of the holding space 39. The connecting rope 40 is fixed to the upper end of the holding block 49 above, and the upper end of the connecting rope 40 connects the upper wall of the holding space 39 and the upper wall of the position limiting space 48 on the right. penetrating fixedly connected to the support rod 46, wherein the bottom left corner of the annular interference plate 11 traction rope 36 is fixedly connected, the traction rope 36 and left and right walls of the lower end before bellflower lifting space 39 The tow rope 36 is fixedly connected to the slider 45 through the left wall of the sliding space 43, and the tow rope 36 is sandwiched between the two sandwiches in the sandwiching space 39. The storage space 12 is sandwiched by the holding blocks 49, and a division mechanism 60 for dividing the storage space 12 into two spaces is provided in the storage space 12, and an auxiliary mechanism 62 is provided on the lower wall of the annular space 13. The auxiliary mechanism 62 can more easily discharge the rice from the storage space 12 by mixing the rice, and the rice discharge mechanism 63 capable of discharging the rice is provided in the storage space 12 below the split mechanism 60. The rice filling mechanism 61 automatically puts rice from the rice bag into the rice bowl 10, avoiding spills of rice and saving time and labor, and the splitting mechanism 60 and the rice discharging mechanism 63 make new rice. And old rice can be separated, and mixing can be avoided.

Advantageously, the dividing mechanism 60 includes a dividing plate 52 fixed in the storage space 12 and dividing the storage space 12, and the upper and lower surfaces of the dividing plate 52 are contained in the dividing plate 52. A penetrating space 55 is provided, a sensor 56 is fixedly provided in the left wall of the penetrating space 55, and an extrusion groove 53 that opens downward is provided in each of the left and right walls of the penetrating space 55. A connecting block 57 having a lower end located in the storage space 12 is provided in the extrusion groove 53, and the connecting block 57 and the upper wall of the extrusion groove 53 are further provided in the extrusion groove 53. A tension spring 54 is provided, and a position limiting groove 59 is formed in the connecting block 57, and a wall away from the through space 55 in the position limiting groove 59 communicates with the storage space 12. A limiting plate 58 that is fixedly connected to the lower end of the connecting block 57 and can close the penetrating space 55 is provided in the storage space 12, and a wall away from the penetrating space 55 in the extrusion groove 53. The extrusion space 65 is provided in the extrusion space 65 so as to communicate with the extrusion groove 53, and a trapezoidal block 51 having one end located in the extrusion groove 53 is provided in the extrusion space 65. Further, an extrusion spring 50 for repositioning the trapezoidal block 51 is provided inside.

Advantageously, the auxiliary mechanism 62 includes an annular rotation space 33, an annular sealing space 31 is provided between the annular rotation space 33 and the storage space 12, and the outer wall of the annular sealing space 31 has an annular shape. The inner wall communicates with the storage space 12 while communicating with the rotating space 33, and the annular sealing plate 35 is slidably connected in the annular sealing space 31 and into the annular rotating space 33. In, the annular rotating gear 34 is slidably connected, two connecting rods 32 are fixedly connected to the inner wall of the annular rotating gear 34, and one end of the two connecting rods 32 is the annular sealing space 31. The rotating motor 15 is fixedly connected to the upper wall of the annular rotating space 33, and extends to the storage space 12 through the annular sealing plate 35 and the lower end of the rotating motor 15. A rotating shaft 17 is movably connected to the space, and a rotating gear 19 whose left end meshes with the right end of the annular rotating gear 34 is fixed to the lower end of the rotating shaft 17.

Advantageously, the rice discharge mechanism 63 includes a discharge space 25 that communicates the storage space 12 with the outside, and an electromagnetic switch 26 that can be operated intermittently is provided in the discharge space 25. An annular support plate 64 is provided in the storage space 12, two spring grooves 22 that open upward are formed in the lower wall of the storage space 12, and the upper end of the spring groove 22 supports the annular support. A spring block 21 fixedly connected to the plate 64 is provided, a telescopic spring 28 for supporting the spring block 21 is further provided in the spring groove 22, and a chain 27 and a rope are provided at the lower end of the spring block 21. An annular tub 24 whose upper end is fixedly connected to the annular support plate 64 is provided in the discharge space 25 which is fixedly connected to the 23, and a triangular plate 30 is provided above the annular support plate 64. Two elevating grooves 20 are provided in the triangular plate 30, and the penetrating portion of the elevating groove 20 penetrates the end surface of the triangular plate 30 near the inner wall of the storage space 12, and the elevating groove 20 is provided. An elevating block 29 that can be raised and lowered is provided inside, and one end of the connecting rod 32 penetrates the wall of the elevating groove 20 and is fixedly connected to the elevating block 29. The alarm 16 controlled by the sensor 56 is fixed, a push switch 18 capable of controlling the operation of the electromagnetic switch 26 is further fixedly connected to the right surface of the rice paddle 10, and the lower end of the rope 23 is the spring. The lower wall of the groove 22 and the upper wall of the extrusion groove 53 are fixedly connected to the connecting block 57, and the lower end of the chain 27 is the lower wall of the spring groove 22 and the wall of the extrusion space 65. Is fixedly connected to the trapezoidal block 51 through.

Advantageously, the elasticity of the support spring 14 is weaker than the gravity of the lid plate 38, and the elasticity of the sliding spring 44 is weaker than the frictional force between the two sandwiching blocks 49 and the tow rope 36. The elasticity of the tension spring 54 is stronger than the elasticity of the extrusion spring 50, and the elasticity of the telescopic spring 28 is stronger than the elasticity of the extrusion spring 50.

First, the tension spring 54 and the sliding spring 44 are in a tension state, the support spring 14 and the expansion spring 28 are in a compression state, and the storage space 12 is packed with rice.

To take rice in a fixed amount, press the push switch 18 to activate the electromagnetic switch 26, and then the rice leaves the storage space 12 and the discharge space 25, and after a certain period of time, the electromagnetic switch 26 automatically operates. The operation is stopped, the discharge space 25 is closed, and the rotation motor 15 is operated by the operation of the electromagnetic switch 26 to drive and rotate the rotation shaft 17 and the rotation gear 19, and then the annular rotation gear 34. And the connecting rod 32 rotate in conjunction with each other, and by rotating the annular sealing plate 35 and the elevating block 29, the triangular plate 30 rotates above the annular support plate 64 and moves the rice deposited in the storage space 12. , The rice is not blocked when it is discharged.

If there is no rice in the penetrating space 55, the sensor 56 controls and activates the alarm 16 to indicate to the user that there is a shortage of rice by the alarm 16, and since there is no rice in the penetrating space 55, the tension spring 54 is By repositioning and raising the connecting block 57 and the limiting plate 58, the penetrating space 55 is closed by the limiting plate 58 and the storage spaces 12 above and below the dividing plate 52 are blocked so that they cannot communicate with each other, and the connecting block 57 rises. When the trapezoidal block 51 is returned to the extrusion space 65 and the extrusion spring 50 is compressed and the connecting block 57 is raised along the position limiting groove 59 to the same height as the extrusion space 65, the extrusion spring 50 is repositioned and the trapezoidal block The 51 is inserted into the position limiting groove 59 to limit the descent of the connecting block 57.

To put rice in the storage space 12, the lid plate 38 is manually circulated to communicate the storage space 12 with the outside, and then a rice bag filled with rice is placed above the support rod 46, and the lid plate 38 is a rice paddle. Since the support spring 14 is repositioned and raises the annular obstruction plate 11 because it is separated from the upper part of 10, the annular obstruction plate 11 is positioned outside, that is, the rice does not spill when the rice is discharged from the rice bag, and the annular obstruction plate 11 is discharged. When the tow rope 36 is loosened by the ascent of 11 and the rice bag is placed on the support rod 46, the support rod 46 is lowered and the position limiting space 48 is compressed, and the connecting rope 40 is pulled by the lowering of the support rod 46 and is moved up. The pinching block 49 is raised to compress the pinching spring 41, and the two pinching blocks 49 no longer pinch the tow rope 36. Here, the sliding spring 44 is repositioned and the slider 45 and the blade 42 are moved to the right. The upper end of the blade 42 cuts through the lower end of the rice bag, the rice enters above the dividing plate 52 from the cut end by its own weight, and when all the rice in the rice bag has fallen, the rice bag can be easily removed.

After stuffing the rice, push the annular obstruction plate 11 downward by hand, go around the lid plate 38, close the storage space 12 again by the lid plate 38, and the support spring 14 is restored and pulled by the lowering of the annular obstruction plate 11. The rope 36 is also pulled, and by removing the rice bag, the position limiting space 48 is repositioned with the support rod 46, and then the connecting rope 40 is loosened, and the pinching spring 41 is repositioned to lower the upper pinching block 49. Here, the holding block 49 holds the tow rope 36 again, and when the annular obstruction plate 11 descends and pulls the tow rope 36, the slider 45 and the blade 42 are interlocked to return to the left.

When the old rice below the dividing plate 52 is used up, the telescopic spring 28 is repositioned, and by interlocking the spring block 21, the annular support plate 64 and the annular tub 24 are raised, and then the triangular plate 30 is interlocked and raised. , The rise of the spring block 21 tightens the chain 27 and the rope 23, the chain 27 returns the trapezoidal block 51 to the extrusion space 65, the connecting block 57 is no longer restricted, and the gravity of the new rice in the through space 55 causes the limiting plate 58. And the connecting block 57 descends, the tension spring 54 is pulled again, the new rice goes from the upper side to the lower side of the split plate 52, and the annular support plate 64 and the spring block 21 are lowered again, so that the telescopic spring 28 is renewed. In the compressed state, the chain 27 and the rope 23 are loosened again, and the extrusion spring 50 repositions the trapezoidal block 51.

According to the above method, an engineer in the field can make various modifications according to the working situation within the scope of the present invention.

Claims (5)

A storage space that includes a rice bowl and opens upward is provided in the rice bowl, a rice filling mechanism that automatically inserts rice is provided in the rice bowl, and the rice filling mechanism is the rice. A hinge plate whose lower end is fixedly connected to the rice bowl is fixed to the left end of the lid plate, which includes a lid plate which is located above the tray and can block the storage space. An annular space is provided in the annular space and centered on the storage space, an annular obstruction plate whose upper end abuts on the lid plate is provided in the annular space, and the annular obstruction is further provided in the annular space. Two support springs for supporting the plate are provided, position limiting spaces are provided on the left and right walls of the storage space so as to communicate with the storage space, and support rods are provided in the storage space. The left and right ends of the support rod are located in the position-restricted space on the left and the position-restricted space on the right, respectively, and a compression spring whose upper end is fixedly connected to the support rod on the lower wall of the position-restricted space. Is fixed, a sliding space is provided in the support rod, the upper wall of the sliding space communicates the storage space and the position limiting space, and the right wall of the sliding space The sliding spring is fixedly connected, the slider is fixedly connected to the left end of the sliding spring, and the blade whose upper end is located in the position limiting space on the left is fixed to the upper end of the slider. A holding space is provided in the left wall of the position limiting space, two holding blocks are provided in the holding space, and the lower end of the holding block below is fixed to the lower wall of the holding space. The upper holding block is fixedly connected to the upper end of the holding spring, the upper end of the holding spring is fixedly connected to the upper wall of the holding space, and the upper holding block is fixed to the upper end of the connecting rope. The upper end of the connecting rope penetrates the upper wall of the holding space and the upper wall of the position limiting space on the right and is fixedly connected to the support rod, and the tow rope is fixed to the left lower end of the annular obstruction plate. The lower end of the tow rope penetrates the lower wall of the annular space, the left and right walls of the holding space, and the left wall of the sliding space, and is fixedly connected to the slider. In the space, the tow rope is sandwiched by the two sandwiching blocks, a dividing mechanism for dividing the storage space into two spaces is provided in the storage space, and an auxiliary mechanism is provided on the lower wall of the annular space. The auxiliary mechanism can more easily discharge rice from the storage space by mixing rice, and a rice discharge mechanism capable of discharging rice is provided in the storage space below the division mechanism, and the rice is discharged. The rice filling mechanism automatically puts rice from the rice bag into the rice bowl, avoiding spillage of rice, saving time and labor, and separating new rice and old rice by the dividing mechanism and the rice discharging mechanism. A rice bowl that is easy to put in rice and can separate rice, which is characterized by avoiding mixing. The division mechanism includes a division plate fixed in the storage space and dividing the storage space, and a penetration space penetrating the upper and lower surfaces of the division plate is provided in the division plate, and the penetration space is provided. A sensor is fixedly provided in the left wall of the space, and an extrusion groove that opens downward is formed in each of the left and right walls of the penetration space, and the lower end of the extrusion groove is the storage space. A connecting block located inside is provided, a tension spring for connecting the connecting block and the upper wall of the extrusion groove is further provided in the extrusion groove, and a position limiting groove is formed in the connecting block. In the position limiting groove, the wall away from the penetrating space communicates with the storage space, and the storage space is fixedly connected to the lower end of the connecting block and the penetrating space can be closed. A plate is provided, and the extrusion space is provided in the wall away from the through space in the extrusion groove so as to communicate with the extrusion groove, and one end of the extrusion space is located in the extrusion groove. The rice paddle according to claim 1, wherein the trapezoidal block is provided, and an extrusion spring for repositioning the trapezoidal block is further provided in the extrusion space. .. The auxiliary mechanism includes an annular rotation space, and an annular sealing space is provided between the annular rotation space and the storage space. In the annular sealing space, the outer wall communicates with the annular rotation space, whereas the inner wall is the inner wall. It communicates with the storage space, and an annular sealing plate is slidably connected in the annular sealing space, and an annular rotating gear is slidably connected in the annular rotating space. Two connecting rods are fixedly connected to the inner wall of the space, and one end of the two connecting rods penetrates the annular sealing space and the annular sealing plate and extends to the storage space. A rotating motor is fixedly connected to the upper wall of the annular rotating space, a rotating shaft is movably connected to the lower end of the rotating motor, and the left end is the annular rotating gear at the lower end of the rotating shaft. The rice bowl according to claim 1, wherein the rotating gear that meshes with the right end of the rice is fixed, and the rice can be easily put in and the rice can be separated. The rice discharge mechanism includes a discharge space that communicates the storage space with the outside, an electromagnetic switch that can be operated intermittently is provided in the discharge space, and an annular support plate is provided in the storage space. Two spring grooves that open upward are formed in the lower wall of the storage space, and a spring block whose upper end is fixedly connected to the annular support plate is provided in the spring groove. A telescopic spring for supporting the spring block is further provided in the groove, a chain and a rope are fixedly connected to the lower end of the spring block, and the upper end thereof is connected to the annular support plate in the discharge space. An annular tub that is fixedly connected is provided, two triangular plates are provided above the annular support plate, an elevating groove is formed in the triangular plate, and one wall of the elevating groove serves as the storage space. An elevating block that can be elevated and lowered is provided in the elevating groove, and one end of the connecting rod penetrates the wall of the elevating groove and is fixedly connected to the elevating block. An alarm controlled by the sensor is fixed to the right side, a push switch capable of controlling the operation of the electromagnetic switch is fixedly connected to the right side of the rice paddle, and the lower end of the rope is below the spring groove. The wall and the upper wall of the extrusion groove are fixedly connected to the connecting block, and the lower end of the chain penetrates the lower wall of the spring groove and the wall of the extrusion space and is fixed to the trapezoidal block. The rice spring according to claim 3, wherein the rice is easily put in and the rice can be separated. The elasticity of the support spring is weaker than the gravity of the lid plate, the elasticity of the sliding spring is weaker than the frictional force between the two holding blocks and the tow rope, and the elasticity of the tension spring is the elasticity of the extrusion spring. The rice paddle according to claim 2, wherein the elasticity of the telescopic spring is stronger than that of the extrusion spring, and the rice can be easily put in and the rice can be separated.

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