CN217056056U - Spoon pipe device for hydraulic coupling - Google Patents

Abstract

The utility model discloses a spoon pipe device for a hydraulic coupler, which comprises a shell, an outer spoon pipe, an inner spoon pipe, a fixed pipe, a telescopic driving mechanism, an inner cavity, a flow regulating mechanism, a movable seat, a reversing regulating mechanism, an inner spoon pipe orifice and an outer spoon pipe orifice; in the utility model, the screw rod is driven to rotate by the motor, and the rotation of the screw rod drives the outer spoon pipe and the inner spoon pipe to vertically move together by the movable seat, thereby meeting the requirement that the spoon pipes are filled with oil at different depths; the flow regulating mechanism arranged in the utility model can drive the first spline shaft to rotate through the second motor, and the rotation of the first spline shaft drives the inner spoon pipe to rotate integrally through the first driving gear and the driven gear, so that the pipe orifice of the inner spoon and the pipe orifice of the outer spoon deflect, the oil output of the pipe orifice of the spoon can be directly regulated, and the use convenience is improved; the utility model discloses in set up switching-over adjustment mechanism, can order about outer spoon pipe wholely rotatory, satisfy the needs of equidirectional oil charge.

Description

Spoon pipe device for hydraulic coupler

Technical Field

The utility model relates to a hydraulic coupling technical field, specific spoon pipe device for hydraulic coupling that says so.

Background

A hydraulic coupler is a device which takes liquid as a working medium to realize power transmission between a prime motor and a working machine, and mainly comprises a shell, a pump impeller, a turbine, a scoop tube and the like, when the hydraulic coupler works, working liquid as a transmission medium can do centrifugal motion under the high-speed rotation of the pump impeller, so that the hydraulic coupler can drive the working liquid to do centrifugal motion in different directions when rotating forwards and reversely, the opening direction of the scoop tube can be divided into clockwise and anticlockwise, but the existing scoop tube is fixed in one direction when being installed, when the hydraulic coupler needs to rotate forwards and backwards, the scoop tubes in different opening directions need to be adjusted and replaced according to the steering of the coupler, so that the use efficiency is low, the operation steps are complex, the use cost is high, the scoop tubes in different opening directions need to be equipped, and the adjustment of the scoop tube device of the existing hydraulic coupler is troublesome and inconvenient, thereby affecting the effectiveness of the fluid coupling operation.

SUMMERY OF THE UTILITY MODEL

The above-mentioned weak point that exists among the prior art, the utility model aims at providing a spoon pipe device for hydraulic coupling has solved when current spoon pipe device for hydraulic coupling adjusts more troublesome to influence the problem of hydraulic coupling working effect.

The utility model discloses a realize that the technical scheme that above-mentioned purpose adopted is: the spoon tube device for the hydraulic coupler is characterized by comprising a shell, an outer spoon tube, an inner spoon tube, a fixed tube, a telescopic driving mechanism, an inner cavity, a flow regulating mechanism, a movable seat, a reversing regulating mechanism, an inner spoon tube opening and an outer spoon tube opening; an inner cavity is formed in the upper side of the shell, and a fixed pipe is fixedly connected in the inner cavity; the outer part of the upper side of the outer spoon tube is movably connected inside the inner cavity, and an outer spoon tube opening is formed in the left lower side of the outer spoon tube; the outer part of the inner spoon tube is movably connected with the inner part of the outer spoon tube, an inner spoon tube opening is formed in the left lower side of the inner spoon tube, and the inner upper side of the inner spoon tube is movably connected with the outer part of the lower side of the fixed tube; the telescopic driving mechanism is arranged on the left upper side of the shell; the movable seat is vertically and movably connected inside the inner cavity, and the left side of the movable seat is connected with the telescopic driving mechanism; the flow regulating mechanism is arranged on the left side of the movable seat, and the right side of the flow regulating mechanism is connected with the outer part of the upper side of the inner spoon pipe; the reversing adjusting mechanism is arranged on the right side of the movable seat, and the left side of the reversing adjusting mechanism is connected with the outer side of the upper side of the outer spoon pipe.

Preferably, the specific structure of the telescopic driving mechanism comprises a screw, a threaded hole and a first motor; the first motor is fixedly connected to the outside of the left upper side of the shell; the screw is movably connected to the left side of the inner cavity, and the center of the upper side of the screw is fixedly connected with a lower output shaft of the motor; the threaded hole is arranged inside the left side of the movable seat and is connected with the screw rod.

Preferably, the first motor is a servo motor or a stepping motor.

Preferably, the specific structure of the flow regulating mechanism comprises a motor II, a spline shaft I, a driving gear I and a driven gear I; the second motor is fixedly connected to the left side of the center of the top of the shell; the first spline shaft is movably connected in a vertical hole formed in the left side of the movable seat, and the center of the upper side of the first spline shaft is fixedly connected with an output shaft of the lower side of the second motor; the inner part of the driven gear I is fixedly connected with the outer part of the upper side of the inner spoon tube; the driving gear is movably connected to the inner portion of the left side of the movable seat, a right side tooth portion of the driving gear is connected with a left side tooth portion of the driven gear, and a spline hole formed in the center of the driving gear is connected with the spline shaft I.

Preferably, the second motor is a servo motor or a stepping motor.

Preferably, the specific structure of the reversing adjusting mechanism comprises a motor III, a spline shaft II, a driving gear II and a driven gear II; the motor III is fixedly connected to the right upper side of the shell; the second spline shaft is movably connected into a vertical hole formed in the right side of the movable seat, and the center of the upper side of the second spline shaft is fixedly connected with an output shaft of the third motor; the interior of the driven gear II is fixedly connected with the exterior of the upper side of the outer spoon pipe; the driving gear II is movably connected inside the right side of the movable seat, the left side tooth part of the driving gear II is connected with the right side tooth part of the driven gear II, and the spline hole formed in the center of the driving gear II is connected with the spline shaft II.

Preferably, the motor three is a servo motor or a stepping motor.

The utility model has the advantages that:

(1) the utility model discloses in drive the screw rod rotation through the motor, the rotation of screw rod then drives outer spoon pipe and interior spoon pipe vertical removal together through the sliding seat, has satisfied the spoon pipe and has been in the needs of different degree of depth oil charge.

(2) The utility model discloses in the flow control mechanism who sets up, it is rotatory to drive integral key shaft one through motor two, and the rotation of integral key shaft one then through driving gear one and driven gear drive interior spoon pipe is whole rotatory, makes interior spoon mouth of pipe and outer spoon mouth of pipe take place to deflect, can directly adjust the size of spoon mouth of pipe oil mass output, has improved the convenience when using.

(3) The utility model discloses in set up switching-over adjustment mechanism, it is rotatory to drive integral key shaft two through motor three, and the rotation of integral key shaft two then drives outer spoon pipe rotation through driving gear two and driven gear two, satisfies the needs of equidirectional oil charge.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the telescopic driving mechanism.

FIG. 3 is a schematic structural view of a flow regulating mechanism;

fig. 4 is a schematic structural diagram of the reversing adjustment mechanism.

In the figure: 1-a housing; 2, an outer spoon tube; 3-inner spoon tube; 4-fixing the tube; 5-a telescopic driving mechanism; 6-inner cavity; 7-a flow regulating mechanism; 8-a movable seat; 9-a reversing adjustment mechanism; 10-inner spoon pipe mouth; 11-outer spoon pipe mouth; 51-screw rod; 52-a threaded hole; 53-electric machine one; 71-motor two; 72-spline shaft one; 73-driving gear one; 74-driven gear one; 91-motor three; 92-spline shaft II; 93-driving gear two; 94-driven gear two.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Example 1

As shown in fig. 1, a spoon tube device for a hydraulic coupler comprises a shell 1, an outer spoon tube 2, an inner spoon tube 3, a fixed tube 4, a telescopic driving mechanism 5, an inner cavity 6, a flow regulating mechanism 7, a movable seat 8, a reversing regulating mechanism 9, an inner spoon tube opening 10 and an outer spoon tube opening 11; an inner cavity 6 is formed in the upper side of the shell 1, and a fixed pipe 4 is fixedly connected in the inner cavity 6; the outer part of the upper side of the outer spoon tube 2 is movably connected inside the inner cavity 6, and the left lower side of the outer spoon tube 2 is provided with an outer spoon tube opening 11; the outer part of the inner spoon tube 3 is movably connected with the inner part of the outer spoon tube 2, an inner spoon tube opening 10 is formed in the left lower side of the inner spoon tube 3, and the upper side of the inner part of the inner spoon tube 3 is movably connected with the outer part of the lower side of the fixed tube 4; the telescopic driving mechanism 5 is arranged on the left upper side of the shell 1; the movable seat 8 is vertically and movably connected inside the inner cavity 6, and the left side of the movable seat 8 is connected with the telescopic driving mechanism 5; the flow regulating mechanism 7 is arranged on the left side of the movable seat 8, and the right side of the flow regulating mechanism 7 is connected with the outer part of the upper side of the inner spoon pipe 3; the reversing adjusting mechanism 9 is arranged on the right side of the movable seat 8, and the left side of the reversing adjusting mechanism 9 is connected with the outer side of the upper side of the outer spoon pipe 2.

Example 2

As shown in fig. 1, a spoon tube device for a hydraulic coupler comprises a shell 1, an outer spoon tube 2, an inner spoon tube 3, a fixed tube 4, a telescopic driving mechanism 5, an inner cavity 6, a flow regulating mechanism 7, a movable seat 8, a reversing regulating mechanism 9, an inner spoon tube opening 10 and an outer spoon tube opening 11; an inner cavity 6 is formed in the upper side of the shell 1, and a fixed pipe 4 is fixedly connected in the inner cavity 6; the outer part of the upper side of the outer spoon tube 2 is movably connected inside the inner cavity 6, and an outer spoon tube opening 11 is formed in the left lower side of the outer spoon tube 2; the outer part of the inner spoon tube 3 is movably connected with the inner part of the outer spoon tube 2, an inner spoon tube opening 10 is formed in the left lower side of the inner spoon tube 3, and the upper side of the inner part of the inner spoon tube 3 is movably connected with the outer part of the lower side of the fixed tube 4; the telescopic driving mechanism 5 is arranged on the left upper side of the shell 1; the movable seat 8 is vertically and movably connected inside the inner cavity 6, and the left side of the movable seat 8 is connected with the telescopic driving mechanism 5; the flow regulating mechanism 7 is arranged on the left side of the movable seat 8, and the right side of the flow regulating mechanism 7 is connected with the outer part of the upper side of the inner spoon pipe 3; reversing adjustment mechanism 9 establishes on 8 right sides of sliding seat, reversing adjustment mechanism 9 left sides is connected with outer 2 upside outsides of scoop tubes.

As shown in fig. 2, the specific structure of the telescopic driving mechanism 5 includes a screw 51, a threaded hole 52 and a first motor 53; the first motor 53 is fixedly connected to the outer portion of the left upper side of the shell 1; the screw 51 is movably connected to the left side of the inner cavity 6, and the center of the upper side of the screw 51 is fixedly connected with an output shaft at the lower side of the first motor 53; the threaded hole 52 is formed in the left inner portion of the movable seat 8, and the threaded hole 52 is connected with the screw 51.

The first motor 53 is a servo motor or a stepping motor, so that automatic control is facilitated through an existing automation technology.

Example 3

As shown in fig. 1, a spoon tube device for a hydraulic coupler comprises a shell 1, an outer spoon tube 2, an inner spoon tube 3, a fixed tube 4, a telescopic driving mechanism 5, an inner cavity 6, a flow regulating mechanism 7, a movable seat 8, a reversing regulating mechanism 9, an inner spoon tube opening 10 and an outer spoon tube opening 11; an inner cavity 6 is formed in the upper side of the shell 1, and a fixed pipe 4 is fixedly connected in the inner cavity 6; the outer part of the upper side of the outer spoon tube 2 is movably connected inside the inner cavity 6, and an outer spoon tube opening 11 is formed in the left lower side of the outer spoon tube 2; the outer part of the inner spoon tube 3 is movably connected with the inner part of the outer spoon tube 2, an inner spoon tube opening 10 is formed in the left lower side of the inner spoon tube 3, and the upper side of the inner part of the inner spoon tube 3 is movably connected with the outer part of the lower side of the fixed tube 4; the telescopic driving mechanism 5 is arranged on the left upper side of the shell 1; the movable seat 8 is vertically and movably connected inside the inner cavity 6, and the left side of the movable seat 8 is connected with the telescopic driving mechanism 5; the flow regulating mechanism 7 is arranged on the left side of the movable seat 8, and the right side of the flow regulating mechanism 7 is connected with the outer part of the upper side of the inner spoon pipe 3; reversing adjustment mechanism 9 establishes on 8 right sides of sliding seat, reversing adjustment mechanism 9 left sides is connected with outer 2 upside outsides of scoop tubes.

As shown in fig. 2, the specific structure of the telescopic driving mechanism 5 includes a screw 51, a threaded hole 52 and a first motor 53; the first motor 53 is fixedly connected to the outer portion of the left upper side of the shell 1; the screw 51 is movably connected to the left side of the inner cavity 6, and the center of the upper side of the screw 51 is fixedly connected with an output shaft at the lower side of a motor I53; the threaded hole 52 is arranged inside the left side of the movable seat 8, and the threaded hole 52 is connected with the screw 51.

The first motor 53 is a servo motor or a stepping motor, so that automatic control is facilitated through an existing automation technology.

As shown in fig. 3, the specific structure of the flow rate adjusting mechanism 7 includes a second motor 71, a first spline shaft 72, a first driving gear 73 and a first driven gear 74; the second motor 71 is fixedly connected to the left side of the center of the top of the shell 1; the first spline shaft 72 is movably connected in a vertical hole formed in the left side of the movable seat 8, and the center of the upper side of the first spline shaft 72 is fixedly connected with an output shaft at the lower side of the second motor 71; the inside of the first driven gear 74 is fixedly connected with the outside of the upper side of the inner spoon pipe 3; the driving gear I73 is movably connected to the inner portion of the left side of the movable seat 8, the right side tooth portion of the driving gear I73 is connected with the left side tooth portion of the driven gear I74, and a spline hole formed in the center of the driving gear I73 is connected with the spline shaft I72.

The second motor 71 is a servo motor or a stepping motor, so that automatic control is facilitated through the existing automation technology.

As shown in fig. 4, the specific structure of the reversing adjustment mechanism 9 includes a motor three 91, a spline shaft two 92, a driving gear two 93 and a driven gear two 94; the motor III 91 is fixedly connected to the right upper side of the shell 1; the second spline shaft 92 is movably connected in a vertical hole formed in the right side of the movable seat 8, and the center of the upper side of the second spline shaft 92 is fixedly connected with an output shaft at the lower side of the third motor 91; the interior of the driven gear II 94 is fixedly connected with the exterior of the upper side of the outer spoon pipe 2; the driving gear II 93 is movably connected inside the right side of the movable seat 8, the left side tooth part of the driving gear II 93 is connected with the right side tooth part of the driven gear II 94, and the spline hole formed in the center of the driving gear II 93 is connected with the spline shaft II 92.

The third motor 91 is a servo motor or a stepping motor, so that automatic control is facilitated through the existing automatic technology.

The utility model has the use state that during adjustment, firstly, the first motor 53 in the telescopic driving mechanism 5 drives the screw rod 51 to rotate, and the rotation of the screw rod 51 drives the outer spoon pipe 2 and the inner spoon pipe 3 to vertically move together through the movable seat 8, thereby meeting the requirements of the spoon pipes for oil charging at different depths, and the flow regulating mechanism 7 which is additionally arranged can drive the spline shaft 72 to rotate through the second motor 71, and the rotation of the spline shaft 72 drives the inner spoon pipe 3 to integrally rotate through the first driving gear 73 and the first driven gear 74, thereby enabling the inner spoon pipe orifice 10 and the outer spoon pipe orifice 11 to deflect, and also directly adjusting the output of the oil quantity of the spoon pipe orifice, further improving the convenience during use, and the reversing regulating mechanism 9 which is arranged can drive the second spline shaft 92 to rotate through the third motor 91, and the rotation of the spline shaft two 92 drives the outer spoon pipe 2 to integrally rotate through the second driving gear 93 and the second driven gear 94, the requirement of oil filling in different directions can be met.

The control mode of the present invention is controlled by manual starting or by the existing automation technology, the connection diagram of the power element and the supply of the power source belong to the common knowledge in the field, and the present invention is mainly used for protecting the mechanical device, so the present invention does not explain the control mode and the wiring arrangement in detail.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

The foregoing shows and describes the basic principles and features of the present invention and the advantages thereof, as will be understood by those skilled in the art, and it is not intended to limit the present invention to the details of the foregoing embodiments, but rather to illustrate and describe the principles of the present invention without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents.

Claims (7)

1. A spoon pipe device for a hydraulic coupling is characterized by comprising a shell (1), an outer spoon pipe (2), an inner spoon pipe (3), a fixed pipe (4), a telescopic driving mechanism (5), an inner cavity (6), a flow regulating mechanism (7), a movable seat (8), a reversing regulating mechanism (9), an inner spoon pipe orifice (10) and an outer spoon pipe orifice (11);

an inner cavity (6) is formed in the upper side of the shell (1), and a fixed pipe (4) is fixedly connected in the inner cavity (6);

the outer part of the upper side of the outer spoon tube (2) is movably connected inside the inner cavity (6), and an outer spoon tube opening (11) is formed in the lower left side of the outer spoon tube (2);

the outer part of the inner spoon tube (3) is movably connected inside the outer spoon tube (2), an inner spoon tube opening (10) is formed in the left lower side of the inner spoon tube (3), and the upper side of the inner part of the inner spoon tube (3) is movably connected outside the lower side of the fixed tube (4);

the telescopic driving mechanism (5) is arranged on the left upper side of the shell (1);

the movable seat (8) is vertically and movably connected inside the inner cavity (6), and the left side of the movable seat (8) is connected with the telescopic driving mechanism (5);

the flow regulating mechanism (7) is arranged on the left side of the movable seat (8), and the right side of the flow regulating mechanism (7) is connected with the outer part of the upper side of the inner spoon tube (3);

the reversing adjusting mechanism (9) is arranged on the right side of the movable seat (8), and the left side of the reversing adjusting mechanism (9) is connected with the outer part of the upper side of the outer spoon tube (2).

2. The spoon device for the hydraulic coupler as claimed in claim 1, wherein the specific structure of the telescopic driving mechanism (5) comprises a screw rod (51), a threaded hole (52) and a first motor (53);

the first motor (53) is fixedly connected to the outer portion of the left upper side of the shell (1);

the screw rod (51) is movably connected to the left side of the inner cavity (6), and the center of the upper side of the screw rod (51) is fixedly connected with an output shaft at the lower side of the motor I (53);

the threaded hole (52) is formed in the left inner portion of the movable seat (8), and the threaded hole (52) is connected with the screw rod (51).

3. The spoon device for a fluid coupling as claimed in claim 2, wherein the first motor (53) is a servo motor or a stepper motor.

4. The scoop tube device for a fluid coupling as claimed in claim 1, wherein the specific structure of the flow regulating mechanism (7) comprises a motor II (71), a spline shaft I (72), a driving gear I (73) and a driven gear I (74);

the second motor (71) is fixedly connected to the left side of the center of the top of the shell (1);

the first spline shaft (72) is movably connected in a vertical hole formed in the left side of the movable seat (8), and the center of the upper side of the first spline shaft (72) is fixedly connected with an output shaft at the lower side of the second motor (71);

the inner part of the driven gear I (74) is fixedly connected with the outer part of the upper side of the inner spoon tube (3);

the driving gear I (73) is movably connected to the inner portion of the left side of the movable seat (8), the right side tooth portion of the driving gear I (73) is connected with the left side tooth portion of the driven gear I (74), and a spline hole formed in the center of the driving gear I (73) is connected with the spline shaft I (72).

5. The spoon device for a fluid coupling as claimed in claim 4, wherein the second motor (71) is a servo motor or a stepping motor.

6. The scoop tube device for a hydraulic coupler according to claim 1, wherein the specific structure of the reversing adjustment mechanism (9) comprises a motor three (91), a spline shaft two (92), a driving gear two (93) and a driven gear two (94);

the motor III (91) is fixedly connected to the right upper side of the shell (1);

the second spline shaft (92) is movably connected into a vertical hole formed in the right side of the movable seat (8), and the center of the upper side of the second spline shaft (92) is fixedly connected with an output shaft at the lower side of the third motor (91);

the inner part of the second driven gear (94) is fixedly connected with the outer part of the upper side of the outer spoon tube (2);

the driving gear II (93) is movably connected inside the right side of the movable seat (8), the left side tooth portion of the driving gear II (93) is connected with the right side tooth portion of the driven gear II (94), and the spline hole formed in the center of the driving gear II (93) is connected with the spline shaft II (92).

7. The spoon device of claim 6, wherein the third motor (91) is a servo motor or a stepper motor.

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