CN219111632U - Cuttage rooting agent reaction unit - Google Patents

Abstract

The utility model relates to the technical field of rooting agent reaction, in particular to a cutting rooting agent reaction device which comprises a reaction barrel, wherein a stirring shaft is arranged in the reaction barrel, a valve is arranged at the bottom of the reaction barrel, a feed inlet is formed in the upper end surface of the reaction barrel, four groups of positioning pins are symmetrically arranged on two sides of the feed inlet, and a feeding hopper device with a detachable function is inserted into the feed inlet; the feed hopper device is used for adding rooting agent raw materials such as fulvic acid and humic acid, the feed hopper device is inserted towards the feed inlet, so that a cuboid formed by combining two groups of half shells is inserted into the feed inlet, simultaneously, four groups of positioning pins are respectively inserted into four groups of positioning holes, along with the sliding of the positioning pins along the positioning holes, the two groups of half shells are made to move in opposite directions, the sealing gasket at the joint of the two groups of half shells is extruded and deformed until the inverted inclined surface I staggers the inverted inclined surface II, and the deformed sealing gasket enables the joint of the two groups of half shells to be sealed.

Description

Cuttage rooting agent reaction unit

Technical Field

The utility model relates to the technical field of rooting agent reaction devices, in particular to a cutting rooting agent reaction device.

Background

In the grape cutting seedling raising process, a rooting agent is needed, grape hard branch cutting rooting is difficult, the rooting agent is needed to help the grape hard branch cutting rooting to succeed in cutting rooting, and the grape rooting agent and the breeding method on the market can refer to a grape rooting agent and a grape cutting seedling raising method disclosed in related patent CN110839651B, wherein the rooting agent is prepared from naphthylacetic acid, 5-methyl-3-p-chlorophenyl-2-thiohydantoin, proline, bamboo vinegar and ammonium bicarbonate; most rooting agents mainly comprise fulvic acid and humic acid; the rooting agent needs to be used in a reaction device in the production process; at present, a stirring reaction tank is needed in the reaction manufacturing process of the rooting agent, various materials are poured into the stirring reaction tank through a feed hopper, and various materials in the stirring reaction tank are mixed through a motor driving stirring shaft.

The stirring reaction tank is characterized in that various materials in the stirring reaction tank are mainly divided into liquid and powdery solids, no matter the materials are liquid or solid, when the stirring reaction tank passes through the feeding hopper, the liquid and the solid have residues adhered to the inner wall of the feeding hopper, the feeding hopper is positioned outside the stirring reaction tank, and the feeding hopper cannot be touched when the stirring reaction tank is cleaned, so that the feeding hopper needs to be cleaned independently, and the feeding hopper is generally fixed on the cleaning stirring reaction tank in a welding or bolt fastening mode, so that the feeding hopper cannot be detached or is more troublesome to detach, workers can clean the feeding hopper directly, the cleaning is more troublesome, and meanwhile, some dead corners inside the feeding hopper cannot be cleaned.

Disclosure of Invention

The utility model aims to provide a cuttage rooting agent reaction device, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the cuttage rooting agent reaction device comprises a reaction barrel, wherein a stirring shaft is arranged in the reaction barrel, a valve is arranged at the bottom of the reaction barrel, a feed inlet is formed in the upper end face of the reaction barrel, four groups of positioning pins are symmetrically arranged on two sides of the feed inlet, and a feed hopper device with a detachable function is inserted into the feed inlet;

the feeding hopper device comprises a half shell, two groups of half shells are arranged, one side of each half shell is provided with a welding handle, a limiting frame is arranged on each half shell, a sealing gasket is attached to each half shell, two groups of guide posts are symmetrically connected to two ends of one group of limiting frames, two groups of guide holes are symmetrically formed in two ends of the other group of limiting frames, and an upper cover mechanism is arranged at the upper end of each half shell.

Preferably, the upper cover mechanism comprises a plate body, the tail part of the plate body is connected with a rotary connecting shaft, two groups of rotary connecting sleeves are symmetrically arranged at two ends of the rotary connecting shaft, and a receiving groove is arranged on the rotary connecting sleeve.

Preferably, the locating pin is welded on the reaction barrel, and the end part of the locating pin is provided with an inverted inclined plane I.

Preferably, the two groups of half shells are inserted into the feed inlet, the half shells and the limiting frame are integrally formed, and the guide posts are inserted into the guide holes.

Preferably, two groups of positioning holes are symmetrically formed in the limiting frame, and the positioning holes are spliced with positioning pins.

Preferably, one side in the positioning hole is an inverted inclined plane II, and the inverted inclined plane II is parallel to the inverted inclined plane I.

Preferably, the rotary shaft is connected with the rotary sleeve in a rotary way, and the rotary sleeve is welded on the half shell.

Compared with the prior art, the utility model has the beneficial effects that:

1. the feeding hopper device is inserted towards the feeding hole, a cuboid formed by combining two groups of half shells is inserted into the feeding hole, simultaneously, four groups of positioning pins are respectively inserted into four groups of positioning holes, along with the sliding of the positioning pins along the positioning holes, the first inverted slope at the end part of each positioning pin is abutted against the second inverted slope inside the positioning holes, the first inverted slope is abutted against the second inverted slope and extrudes the second inverted slope, so that the two groups of half shells move in opposite directions, the sealing gasket at the joint of the two groups of half shells is extruded and deformed until the first inverted slope staggers the second inverted slope, and the deformed sealing gasket seals the joint of the two groups of half shells.

2. Secondly, two sets of half shells moving in opposite directions drive two sets of spin-on sleeves to move in opposite directions, so that two ends of a spin-on shaft are respectively inserted into the two sets of spin-on sleeves, and the upper cover mechanism is limited at the upper ends of the two sets of half shells, so that the mounting and dismounting of the feeding hopper device are realized in a plug-in manner of a worker, the mounting and dismounting of the feeding hopper device are facilitated for the worker, the feeding hopper device is detachable, and the cleaning of the feeding hopper device is facilitated for the worker.

Drawings

FIG. 1 is a schematic diagram of the present utility model.

FIG. 2 is a schematic cross-sectional view of the present utility model.

FIG. 3 is a schematic view of a combination of a feeding hopper device and a positioning pin according to the present utility model.

FIG. 4 is a schematic view of the assembly of the feed hopper device of the present utility model.

Fig. 5 is a schematic diagram of a combination of a limiting frame and a positioning pin according to the present utility model.

In the figure: 1. a reaction barrel; 2. a stirring shaft; 3. a valve; 4. a feed inlet; 5. a positioning pin; 51. an inverted slope I; 6. a feed hopper device; 601. a half shell; 602. a handle; 603. a limiting frame; 604. a sealing gasket; 605. a guide post; 606. a guide hole; 607. an upper cover mechanism; 6031. positioning holes; 6032. an inverted slope II; 6071. a plate body; 6072. a rotary connecting shaft; 6073. a rotary jointing sleeve; 6074. and a receiving groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 to 5, the present utility model provides a technical solution: the utility model provides a cuttage rooting agent reaction unit, including reaction barrel 1, set up (mixing) shaft 2 in the reaction barrel 1, reaction barrel 1 bottom sets up valve 3, reaction barrel 1 up end sets up pan feeding mouth 4, pan feeding mouth 4 bilateral symmetry sets up four sets of locating pins 5, pan feeding mouth 4 grafting has the feeder hopper device 6 of dismantling the function, feeder hopper device 6 includes half casing 601, half casing 601 sets up two sets of, half casing 601 one side welding handle 602, set up spacing 603 on the half casing 601, the attached sealed pad 604 of half casing 601, two sets of guide posts 605 of a set of both ends symmetrical connection, two sets of guiding hole 606 are seted up to another set of spacing 603 both ends symmetry, half casing 601 upper end sets up upper cover mechanism 607, wherein sealed pad 604 is the rubber material that has good elasticity, when hopper device 6 is installed to the needs, first merge two sets of half casings 601 along two sets of guiding hole 606 respectively, play the guide effect to two sets of half casing 601, until sealed pad 604 on the half casing 601 are laminated each other, make two sets of half casing 601 merge and be a set of hollow plate body, then place the afterbody 6074 on the rectangular plate 6071, and the end is located on the two sets of rectangular plate 6072, 60 is located on the end pair of the assembly device, 60 is realized respectively, thereby.

The upper cover mechanism 607 comprises a plate body 6071, the tail part of the plate body 6071 is connected with a rotary connecting shaft 6072, two groups of rotary connecting sleeves 6073 are symmetrically arranged at two ends of the rotary connecting shaft 6072, a receiving groove 6074 is arranged on the rotary connecting sleeve 6073, a positioning pin 5 is welded on the reaction barrel 1, an inverted slope I51 is arranged at the end part of the positioning pin 5, two groups of half shells 601 are inserted into a feed inlet 4, the half shells 601 and a limiting frame 603 are integrally formed, a guide post 605 is inserted into a guide hole 606, two groups of positioning holes 6031 are symmetrically arranged on the limiting frame 603, the positioning holes 6031 are inserted into the positioning pin 5, one side in the positioning hole 6031 is an inverted slope II 6032, the inverted slope II 6032 is parallel to the inverted slope I51, the rotary connecting shaft 6073 is welded on the half shells 601, after the feed hopper device 6 is assembled, the feed hopper device 6 is inserted into the rectangular body which is formed by combining the two groups of half shells 601 into the feed inlet 4, simultaneously, four groups of positioning pins 5 are respectively inserted into four groups of positioning holes 6031, along with the sliding of the positioning pins 5 along the positioning holes 6031, the first inverted inclined surface 51 at the end part of the positioning pins 5 is abutted against the second inverted inclined surface 6032 in the positioning holes 6031, the first inverted inclined surface 51 is abutted against the second inverted inclined surface 6032 and presses the second inverted inclined surface 6032, so that the two groups of half shells 601 move in opposite directions, the sealing gasket 604 at the joint of the two groups of half shells 601 is subjected to extrusion deformation until the first inverted inclined surface 51 is staggered with the second inverted inclined surface 6032, the deformed sealing gasket 604 seals the joint of the two groups of half shells 601, the second two groups of half shells 601 which move in opposite directions drive the two groups of rotating joint sleeves 6073 to move in opposite directions, so that the two ends of the rotating joint shaft 6072 are respectively inserted into the two groups of rotating joint sleeves 6073, and the upper cover mechanism 607 is limited at the upper ends of the two groups of half shells 601, therefore, workers can realize the installation and the disassembly of the feeding hopper device 6 in a plug-in a plug manner, thereby the staff of being convenient for installs and dismantles feeder hopper device 6 to feeder hopper device 6 can dismantle, and then the staff of being convenient for washs feeder hopper device 6. When the rooting agent is mixed for reaction, the fulvic acid and the humic acid are poured into the reaction barrel along the feeding hopper device, and then are stirred for mixing reaction.

In the use process, firstly, two groups of half shells 601 are combined, two groups of guide posts 605 are respectively inserted along two groups of guide holes 606 until sealing gaskets 604 on the two groups of half shells 601 are attached to each other, then a plate body 6071 is placed at the upper end of the rectangular body, two ends of a rotating connecting shaft 6072 at the tail part of the plate body 6071 are respectively positioned on two groups of receiving grooves 6074, a feeding hopper device 6 is inserted towards a feeding hole 4, the rectangular body formed by combining the two groups of half shells 601 is inserted into the feeding hole 4, simultaneously four groups of positioning pins 5 are respectively inserted into four groups of positioning holes 6031, as the positioning pins 5 slide along the positioning holes 6031, a first inverted inclined surface 51 at the end part of each positioning pin 5 is abutted against a second inverted inclined surface 6032 in the positioning holes 6031, the first inverted inclined surface 51 is pressed against the second inverted inclined surface 6032, the two groups of half shells 601 are made to move oppositely, and the sealing gaskets 604 at the joint of the two groups of half shells 601 are pressed and deformed until the first inverted inclined surface 51 is staggered with the second inclined surface 6032.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a cuttage rooting agent reaction unit, includes reaction barrel (1), set up (2) in reaction barrel (1), reaction barrel (1) bottom sets up valve (3), and pan feeding mouth (4) are seted up to reaction barrel (1) up end, pan feeding mouth (4) bilateral symmetry sets up four sets of locating pins (5), its characterized in that: the feeding port (4) is inserted with a feeding hopper device (6) with a detachable function;

the feeding hopper device (6) comprises a half shell (601), wherein the half shell (601) is provided with two groups, one side of the half shell (601) is welded with a handle (602), a limiting frame (603) is arranged on the half shell (601), a sealing gasket (604) is attached to the half shell (601), one group of the sealing gaskets is formed by symmetrically connecting two groups of guide posts (605) at two ends of the limiting frame (603), the other group of the sealing gaskets is formed by symmetrically arranging two groups of guide holes (606) at two ends of the limiting frame (603), and an upper cover mechanism (607) is arranged at the upper end of the half shell (601).

2. The cutting rooting agent reaction device according to claim 1, wherein: the upper cover mechanism (607) comprises a plate body (6071), the tail part of the plate body (6071) is connected with a rotary connecting shaft (6072), two groups of rotary connecting sleeves (6073) are symmetrically arranged at two ends of the rotary connecting shaft (6072), and a receiving groove (6074) is formed in the rotary connecting sleeve (6073).

3. The cutting rooting agent reaction device according to claim 1, wherein: the locating pin (5) is welded on the reaction barrel (1), and an inverted slope I (51) is arranged at the end part of the locating pin (5).

4. The cutting rooting agent reaction device according to claim 1, wherein: two groups of half shells (601) are inserted into the feed inlet (4), the half shells (601) and the limiting frame (603) are integrally formed, and the guide post (605) is inserted into the guide hole (606).

5. The cutting rooting agent reaction device according to claim 1, wherein: two groups of positioning holes (6031) are symmetrically formed in the limiting frame (603), and the positioning holes (6031) are inserted with positioning pins (5).

6. The cutting rooting agent reaction device according to claim 5, wherein: one side in the positioning hole (6031) is an inverted inclined plane II (6032), and the inverted inclined plane II (6032) is parallel to the inverted inclined plane I (51).

7. The cutting rooting agent reaction device according to claim 2, wherein: the rotary connecting shaft (6072) is in rotary connection with the rotary connecting sleeve (6073), and the rotary connecting sleeve (6073) is welded on the half shell (601).

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