KR200347793Y1 - Structure of booster pump for milking machine - Google Patents

Abstract

The present invention relates to a booster pump for boosting and supplying a working oil at high pressure so that a crimping cylinder is operated in a hydraulic system of a milking machine used to compress oil such as sesame and perilla and extract oil. According to the screw hole is configured to be fixed to a plurality of hydraulic pumps, the power transmission shaft coupled to the eccentric rotating body is inserted, the vane pump is configured inside, can be selectively converted the number of installation of the hydraulic pump The structure of the booster pump for the milking machine configured to supply the high pressure hydraulic oil to the pressurized cylinder by controlling the inflow of the hydraulic oil introduced from the pump as well as pressurizing the hydraulic oil firstly supplied by the hydraulic pump to the high pressure by the vane pump. It is about.

The purpose of the present invention is to allow the installation of a separate hydraulic pump as an optional number without the first preload by the gear pump to adjust the flow rate of the working oil,

A booster pump for the milking machine configured to supply the boosted hydraulic oil to the compression cylinder by constructing the vane pump by the shaft insertion configuration of the power transmission shaft so that the hydraulic oil preloaded and supplied by the hydraulic pump is boosted to high pressure by the vane pump. In providing a structure.

As a specific means of the present invention for achieving the above object;

A rotor having a plurality of vanes is installed by forming a casing having suction and discharge paths into a main body having a plurality of pairs of screw holes on one side, and as a driving means of the rotor, a power transmission shaft to which an eccentric rotating body is coupled. The screw hole is configured to be inserted into the main body and is provided by installing a separate hydraulic pump as an optional number to provide a booster pump structure for the milking machine is formed to control the flow rate of the working oil.

Description

Structure of booster pump for milking machine

The present invention relates to a booster pump for boosting and supplying a working oil at high pressure so that a crimping cylinder is operated in a hydraulic system of a milking machine used to compress oil such as sesame and perilla and extract oil. According to the screw hole is configured to be fixed to a plurality of hydraulic pumps, the power transmission shaft coupled to the eccentric rotating body is inserted, the vane pump is configured inside, can be selectively converted the number of installation of the hydraulic pump The structure of the booster pump for the milking machine configured to supply the high pressure hydraulic oil to the pressurized cylinder by controlling the inflow of the hydraulic oil introduced from the pump as well as pressurizing the hydraulic oil firstly supplied by the hydraulic pump to the high pressure by the vane pump. It is about.

In general, a milking machine is mainly used to extract vegetable oil from grains such as sesame seeds and perilla, and a hydraulic device is applied as a means of compressing grains by the milking machine.

The hydraulic device applied to the milking machine is configured to pressurize the hydraulic oil through the first and second by the power transmission shaft and the gear pump operated by the drive motor,

It primarily supplies hydraulic oil with a constant pressure on the hydraulic line by using a gear pump to operate the compression cylinder for pressing and oiling the grain, and reciprocates the hydraulic oil boosted to a constant pressure by the power transmission shaft. The hydraulic pump which performs the movement was pressurized by the built-in hydraulic cylinder, so that the high pressure hydraulic fluid was supplied to the compression cylinder, and it was comprised so that the compression work of various grains may be performed.

At this time, the hydraulic cylinder 100 is a piston 10 for adjusting a plurality of high pressure, medium pressure, low pressure as shown in Figure 1 is built, so that the hydraulic pressure is formed by the reciprocating movement of the piston 10 As,

As the power connecting means for driving the piston 10 of such a hydraulic cylinder 100;

The drive gear 30 is constituted by a power transmission shaft 20 which is belt-connected to the drive motor of the milking machine, and a crank shaft 40 geared with the drive gear 30 is formed, and the crank shaft 40 of the Position the hydraulic cylinder 100 formed with a plurality of piston insertion holes 50 in the adjacent position,

A plurality of pistons 10 are fixed to the crankshaft 40 and fixed to the hydraulic cylinder 100 by inserting the other side into the piston insertion hole 50 of the hydraulic cylinder 100,

This causes the reciprocating motion of each of the power transmission shaft 20 rotated by the drive motor and the crank shaft 40 connected by the driven gear to reciprocate, thereby pumping the hydraulic oil filled into the hydraulic cylinder 100 at high pressure. Was to be done.

However, in the conventional milking machine hydraulic device having the configuration as described above, the hydraulic cylinder 100 is a first crank shaft by the gear pump means for increasing the hydraulic oil supplied to the interior of the hydraulic cylinder 100 as a separate crankshaft 40 As a result of the application of the piston (10) by means of), not only does it require a complicated mechanism to drive the piston (10), ie to drive the crankshaft (40), but also because of this complex connection structure, Since it should be used as a factor to increase the manufacturing cost of the milking machine, as well as having a problem of lowering the energy utilization efficiency due to energy loss caused by a complex connection structure,

In the high, medium and low pressure piston 10 is connected to the crankshaft 40 to perform the pumping operation at the same time, each takes a divided form and is connected to the crankshaft 40 by the connecting rod 60 Due to the complicated operation structure that reciprocates in a certain space, the installation work is very difficult, and the space in the hydraulic device for installation is also difficult, and due to excessive pressure due to its own breaking strength, It was a problem that could be broken.

Therefore, the present invention was devised to solve the general problems of the conventional booster pump structure for the milking machine,

The purpose of the present invention is to allow the installation of a separate hydraulic pump as an optional number without the first preload by the gear pump to adjust the flow rate of the working oil,

A booster pump for the milking machine configured to supply the boosted hydraulic oil to the compression cylinder by constructing the vane pump by the shaft insertion configuration of the power transmission shaft so that the hydraulic oil preloaded and supplied by the hydraulic pump is boosted to high pressure by the vane pump. In providing a structure.

As a specific means of the present invention for achieving the above object;

A rotor having a plurality of vanes is installed by forming a casing having suction and discharge paths into a main body having a plurality of pairs of screw holes on one side, and as a driving means of the rotor, a power transmission shaft to which an eccentric rotating body is coupled. The screw hole is configured to be inserted into the main body and is provided by installing a separate hydraulic pump as an optional number to provide a booster pump structure for the milking machine is formed to control the flow rate of the working oil.

1 is a configuration diagram of a booster pump for a conventional milking machine

2 is a partially exploded perspective view of the booster pump for the milking machine according to the present invention

Figure 3 is a longitudinal sectional view of the booster pump for the milking machine according to the present invention

4 is a state in which a separate hydraulic pump installed in the booster pump for the milking machine according to the present invention

5 is a hydraulic operation state of the booster pump for the milking machine according to the present invention

<Explanation of symbols for major parts of drawing>

1: Boosting pump body 2: Casing 3,3 ', 3 ": Thread hole

4: rotor 5: power transmission shaft 6: eccentric rotor

7,7 ': hydraulic pump 8: storage tank 11: fixture

21,21 ': Suction furnace 22,22': Discharge furnace 41: Vane

42: cam ring 51: eccentric protrusion 52: fixing groove

61: circular coupling hole 62: retaining ring 71: fixing hole

72: between operation 73: discharge port 211,211 ': suction port

221,221 ': discharge port B, b: bearing L: pipe connection

M: Drive motor S, S ': Hydraulic oil P: Pulley

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a partially exploded perspective view of the booster pump for the milking machine according to the present invention, Figure 3 is a longitudinal sectional view of the booster pump for the milking machine according to the present invention, Figure 4 is a separate hydraulic pump to the booster pump for the milking machine according to the present invention 5 is a state diagram installed, and looks at its configuration as a hydraulic action state diagram of the booster pump for the milking machine according to the present invention;

A casing 2 composed of the inner center of the main body 1 and having suction and discharge passages 21, 21 ′, 22 and 22 ′, and a screw hole 3 formed in a plurality of pairs on one side of the main body 1. , 3 ', 3 "), a rotor 4 built into the casing 2 and to which a plurality of vanes 41 are coupled, a power transmission shaft 5 to which the rotor 4 is axially coupled, The power transmission shaft 5 is composed of an eccentric rotating body 6 coupled to one end.

At this time, the main body 1 has a rectangular shape as shown in Fig. 2, the fixture 11 is formed at both ends of the bottom surface and the suction and discharge passages 21, 21 ', 22, 22' as the inner central portion. Casing 2 having) is formed,

Such a casing 2 is configured as shown in FIG. 3 and a conventional flat vane pump is installed therein, which is a rotor in which a plurality of vanes 41 are coupled into an elliptical cam ring 42. (4) is inserted and is operated to pressurize the hydraulic oil by compressing the hydraulic oil sucked between the vanes (41) to the discharge side, the rotor (4) is axially coupled to the power transmission shaft (5) which will be described later as its drive means will be.

In addition, the suction passages 21 and 21 'include upper and lower portions of the suction ports 211 and 211' and the cam ring 42, which are configured in one pair on one side and the other side of the upper surface of the main body 1, as shown in FIG. It is a two-way hydraulic passage connecting, the discharge passage (22, 22 ') is a hydraulic passage connecting the discharge port 221 consisting of the center of the upper surface of the main body 1 and the upper and lower portions of the cam ring, they are the main body 1) It is to be sealed in the interior.

In addition, the screw hole 3 is composed of at least five pairs in the form of a pair of two screw holes on one side of the main body 1, as shown in Figure 2,

In configuring such a screw hole (3, 3 ', 3 "), the pair of screw hole forming position is preferably configured to be the same as the position of the fixed hole 71 of the pair of hydraulic pump (7) to be described later, The configuration positions of the respective screw holes 3, 3 ', 3 "are preferably configured on the rotation circumference of the eccentric rotating body 6 which will be described later.

On the other hand, the power transmission shaft 5 is a rod-shaped body having a length as shown in Figures 2 to 3 to be fixed to the pulley (P) for the connection with a separate drive motor (M) on the other side,

One side of the power transmission shaft 5 is preferably configured to integrally constitute an eccentric protrusion 51 protruding from the eccentric position.

In addition, the eccentric rotating body (6) has a cylindrical shape as shown in Figure 2, a circular coupling hole 61 is configured in the center, the outer circumference is configured by the coupling of the bearing (B) In that,

It is coupled to the above-described eccentric protrusions 51, and the fixing means constitutes a fixing groove 52 at the outer circumference of the eccentric protrusion and applies a fixing ring 62 fitted to the fixing groove 52. This is preferred.

Thus, looking at the coupling state and the resulting interaction between each component of the boost pump according to the present invention is configured as described above;

As shown in FIG. 3, first, the power transmission shaft 5 moves the main body 1 in a state in which the rotor 4 into which the cam ring 42 is fitted is coupled to the power transmission shaft 5. The bearing 4 is coupled through the power transmission shaft 5 at one side and the other side of the casing 2 so that the rotor 4 is installed in the casing 2 and penetrates the rotor 4. The eccentric protrusion (51) protruding to one side is fixed to the eccentric rotating body (6), the inlet, discharge port (211, 221 ', 221) consisting of the upper surface of the main body (1) fixed installation of the pipe connector (L) This completes the assembly.

Thus, the assembly of the boost pump in this article is fixed to be installed inside the hydraulic oil storage tank 8, as shown in Figure 4,

This belt-connects the pulley (P) of the power transmission shaft (5) and the drive motor (M) as shown, and fixes the fixture (11) to the inner surface of the storage tank (8), one side screw hole (3) As shown in Fig. 4, the hydraulic pump (7) in which the operation period (72) is internally bolted, and the discharge port (73) of the hydraulic pump (7, 7 ') is the suction port (211) of the boost pump. ) Is installed while connecting to,

At this time, the operation period 72 of the hydraulic pump (7, 7 ') is fixed to the screw hole (3) and the fixing hole formed around the eccentric rotating body (6) to be fixed at a position close to the eccentric rotating body (6) After matching (71), bolt fastening is preferred,

The hydraulic pumps 7 and 7 'installed in this way are basically two as installed on the screw hole 3, as shown in FIG. 4, and if necessary, the hydraulic pumps have the same shape as the A portion shown in FIG. By changing the position of the screw holes (3 ', 3 ") to which the pump is coupled, by installing one additional hydraulic pump, it is possible to adjust the amount of hydraulic oil (S) supplied to the casing (2).

Therefore, the boost pump according to the present invention fixedly installed as the hydraulic device of the milking machine as described above, as shown in FIG.

When the eccentric rotor 6 and the rotor 4 rotate by the rotation of the power transmission shaft 5 by the drive motor M,

As the eccentric rotor 6 rotates, the operation 72 of the hydraulic pumps 7 and 7 ′ fixed to the adjacent position is pumped every time the eccentric rotor 6 performs one rotation. The hydraulic oil (S) filled into the tank (8) is introduced, and is preloaded first,

The preloaded hydraulic oil S is introduced into the two suction paths 21 and 21 'through a pair of suction ports 211.211' connected to the discharge ports 73 of the hydraulic pumps 7 and 7 'and is rotated. (41) is boosted in the form of pushing from the suction side to the discharge side,

The pressurized hydraulic oil S 'is discharged through the bifurcated discharge paths 22 and 22' and sent to the compression cylinder, thereby compressing the grain.

As described above, the booster pump for the milking machine according to the present invention is coupled to the hydraulic pump having the operation period as an optional number, if necessary, by driving the operation between the operation of the hydraulic pump installed by the rotational force of the eccentric rotor to pre-load the hydraulic fluid As a result, the structure can be simplified and the manufacturing cost of the milking machine can be reduced by allowing the operation to create and supply hydraulic pressure between the operations, and to control the inflow of hydraulic oil introduced by converting the number of installation of the optional hydraulic pump. And a very useful design for the producer.

Claims (1)

Cam ring is formed by the casing (2) having the suction, discharge passage 21, 21 ', 22, 22' into the inside of the main body 1 is composed of a plurality of pairs of screw holes (3, 3 ', 3 ") on one side The rotor 4 is fitted into the inside of the 42 and a plurality of vanes 41 are coupled to each other, and the power transmission shaft 5 to which the eccentric rotor 6 is coupled as a driving means of the rotor 4 is provided. It is configured by inserting the main body 1 into the screw hole (3, 3 ', 3 ") to install a separate hydraulic pump (7, 7') as a pair to control the flow rate of the hydraulic oil (S) Booster pump structure for the milking machine characterized in that formed.