KR200207868Y1 - Upper soil production machine of rotavator type - Google Patents

Abstract

The present invention relates to a rotator-type soil maker, and more particularly, to a rotator-type soil maker that is capable of efficiently generating fine soil used for nail seats by mechanized means.

According to the present invention, a conventional rotary rotator provided with a rotary shaft 20 rotated by a driving force such as a tractor, tiller or manager, and a plurality of rotary blades 22 installed at regular intervals on the rotary shaft 20. In the upper part of the rotary shaft 20, the back plate 40 is installed horizontally, and is installed at the lower end of the back plate 40 is formed in a substantially U-shape to surround the rotary blade 22 and the side It is configured to include a net body 50 is formed with an opening 52, the pulverized matter such as soil loaded on the back plate 40 is introduced into the net body 50 through the inlet 30, the rotary The small particles pulverized by the blade 22 are discharged downward through the mesh 50, and relatively large particles such as stones are configured to be discharged through the opening 52 on the side of the mesh 50. A rotator-type topsoil maker is provided.

Description

Upper soil production machine of rotavator type

The present invention relates to a rotator-type soil maker, and more particularly, to a rotator-type soil maker that is capable of efficiently generating fine soil used for nail seats by mechanized means.

In general, soil used for mosquitoes, which are seeded with rice seed, uses fine soil having a relatively small particle size so that the germination of grain can proceed smoothly. In order to obtain such fine soil, a method of conventionally using a method in which a predetermined wire mesh is inclined and sprayed on the wire mesh to remove coarse soil and gravel is used. However, since this method is made by hand, there is a problem in that it takes a lot of work, takes a lot of time, and lowers work efficiency.

The present invention is to solve the problems as described above, an object of the present invention is to provide a rotarator-type clay soil making machine that can efficiently produce fine soil used for the nail spots, etc. by a mechanized means.

1 is a front view of a rotator-type clay soil production machine according to the present invention

2 is a side view of FIG. 1

<Explanation of symbols for main parts of the drawings>

20. Rotary shaft 22. Rotary blade

30. Slot 32. Cover

40. Back 50.

52. Opening 60. Mudguard plate

64. First Pinhole 65. Second Pinhole

According to the present invention, a conventional rotary rotator provided with a rotary shaft 20 rotated by a driving force such as a tractor, tiller or manager, and a plurality of rotary blades 22 installed at regular intervals on the rotary shaft 20. In the upper part of the rotary shaft 20, the back plate 40 is installed horizontally, and is installed at the lower end of the back plate 40 is formed in a substantially U-shape to surround the rotary blade 22 and the side It is configured to include a net body 50 is formed with an opening 52, the pulverized matter such as soil loaded on the back plate 40 is introduced into the net body 50 through the inlet 30, the rotary The small particles pulverized by the blade 22 are discharged downward through the mesh 50, and relatively large particles such as stones are configured to be discharged through the opening 52 on the side of the mesh 50. A rotator-type topsoil maker is provided.

Hereinafter, described with reference to the accompanying drawings, preferred embodiments of the present invention is as follows.

1 and 2 illustrate an embodiment of a rotator-type topsoil maker according to the present invention. The rotator-type topsoil maker according to the present invention includes a rotary shaft 20 having a plurality of rotary blades 22, a back plate 40 positioned on the top of the shaft 10, and a lower end of the back plate 40. It is composed of a network 50 installed in.

As shown in FIG. 1, the rotary shaft 20 is provided with a plurality of rotary blades 22 at regular intervals along its longitudinal direction, and side gears 5 are provided at one side thereof. The shaft 20 is rotated by the side gear part 5 receiving the driving force of a power transmission shaft such as a tractor or a cultivator.

The back plate 40 is installed horizontally on the upper portion of the rotary shaft 20, as shown in Figs. 1 and 2, the inlet 30 is formed at a predetermined position on the upper surface, the inlet 30 The cover 32 is bolted and installed. In addition, the back plate 40 has fixing brackets 42 extending upwardly on both side surfaces of the rear end thereof, and fixing holes 44 are formed on the rear end upper surface of the fixing bracket 42, and pinholes are formed at the lower ends thereof. The lower bracket 46 in which (6) was formed is provided. Here, the input port 30 may be installed on one surface of the net 50 to be described later without separately installing the back plate 40, and thus, a substance such as soil may be introduced into the net 50.

On the other hand, at the rear end of the back plate 40, as shown in Figure 2, the mudguard plate 60 is installed, the front plate 70 is installed substantially vertically at the front end. The mudguard plate 60 has a bracket 62 protruding rearward from both sides thereof, and a first pin hole 64 is formed at an upper end of the bracket 62, thereby being pinned to the back plate 40. . In addition, a second pin hole 65 is formed at the rear end of the first pin hole 64 so that the mudguard plate 60 is pivoted upward to insert the pin in accordance with the fixing hole 44 of the fixing bracket 42. It is fixed in the state parallel to the back plate (40).

As shown in FIG. 1, the mesh 50 is composed of a mesh net 54 having a predetermined area and a frame 55 provided on both sides of the mesh 54. Bolted to the lower bracket 46 of the back plate 40 is installed on the bottom of the back plate (40). The net body 50 is formed in a substantially U shape so as to surround the rotary blade 22, and an opening portion 52 is formed on both sides or one side surface of the net body 50.

According to the rotator-type clay soil making machine configured as described above, the mudguard plate 60 is rotated upward to fix the mudguard plate 60 in parallel with the back plate 40 so that the front plate 70 and the back plate 40 and the mud plate ( 60 is formed, the cover 32 is bolted to the inlet 30 of the back plate 40 is separated and lifted up, and when the object to be loaded such as soil to be loaded in this loading box, The pulverized material is introduced into the net body 50 through the inlet 30 and is pulverized by the rotary blade 22. As the pulverized material is pulverized, fine soil having a small particle size is discharged to the lower portion of the mesh 50, and relatively large gravel or uncrushed coarse soil is formed at the side of the mesh 50. Discharged laterally through 52. At this time, the pulverized matter such as soil may be introduced through the lateral opening 52 of the mesh 50.

According to the present invention as described above, unlike the conventional rotator-type clay soil extractor to extract the fine soil by hand, fine particles of fine particles by grinding the pulverized matter such as soil by a rotary blade that is continuously rotated Since the soil is continuously generated, the productivity is remarkably increased, and there is an advantage that it can work conveniently.

Claims (1)

In the rotary rotator provided with a rotary shaft 20 is rotated by receiving a driving force of a tractor, tiller or manager, and a plurality of rotary blades 22 provided at a predetermined interval on the rotary shaft, the rotary The back plate 40 which is installed substantially horizontally on the upper part of the shaft 20, and is installed at the lower end of the back plate 40 and formed in a substantially U-shape to surround the rotary blade 22, the opening portion 52 on the side It is configured to include a mesh 50 is formed, the pulverized matter such as soil loaded on the back plate 40 is introduced into the mesh 50 through the inlet 30, into the rotary blade 22 The small particles pulverized by the discharged to the lower through the mesh 50, the relatively large particles, such as stone is rotava-type clay soil maker, characterized in that configured to be discharged through the opening 52 of the side of the network 50 .