KR101015840B1 - Apparatus for manufacturing a bushing in an hydraulic pump - Google Patents

Abstract

PURPOSE: A machining apparatus for a bushing of a hydraulic pump is provided to manage a gap between a gear pump housing and a bushing by reduction in the error range of a vertical processing surface. CONSTITUTION: A machining apparatus(100) for a bushing of a hydraulic pump comprises a rotating unit, a machining unit, and a power transmitting unit. One or more bushings are set in a setting jig of a first rotating plate(120) of the rotating unit. The first and second bodies of the bushing are machined by the power of a main motor(140) of a power transmitting unit, simultaneously. As the bushing is vertically machined by an end mill of a machining jig of the machining unit with being fixed in the setting jig, the machining error range of the upper and lower parts of the bushing can be reduced.

Description

Hydraulic pump bushing processing equipment {Apparatus for manufacturing a bushing in an hydraulic pump}

The present invention relates to a processing device for a hydraulic pump bushing, and more particularly, to a processing device for a bushing installed in a housing of a hydraulic pump, which simultaneously processes a first body and a second body of bushings opposed to each other. Of course, by simultaneously machining at least one bushing, it is possible to mass-produce according to the rapid processing, and the gear bushing housing and its housing have a small margin of error due to the vertical machining surface because the end bush is vertically raised and fixed bushing. It relates to a hydraulic pump bushing processing apparatus that facilitates clearance management between bushings installed therein.

In general, a hydraulic pump is a device that converts externally supplied mechanical energy into pressure energy of hydraulic system hydraulic fluid. It is a gear type that rotates by using a gap between two rotating gear teeth. A vane type that pushes and compresses the hydraulic fluid by using a vane installed on the shaft, and a rotary piston type that compresses the volume in several cylinders installed vertically or parallel to the rotating axis by making it smaller according to the rotational direction of the shaft. piston type) and reciprocating piston type, which converts the rotary motion into reciprocating motion and pressurizes the hydraulic oil in the cylinder with the piston.

Current general hydraulic pump 200, as shown in Figure 1, the drive gear 210 and the driven gear 212 is rotatably housed in a housing consisting of the body 214 and the cover 216, the drive gear 210 And a side plate 218 (218a) formed of a thin plate partitioning a high pressure region and a low pressure region during driving of the gear pump between the side of the driven gear 212 and the body 214 or the cover 216 opposite thereto.

However, the above-described thin plate 218 and 218a are extremely thin, which makes it impossible to mount a seal that can block internal leakage during gear pump operation. As it flows into the side, the volumetric efficiency is extremely poor.

In view of this, the tooth width of the gears 210 and 212 and the allowable tolerances of the side plates 218 and 218a are reduced to prevent internal leakage during gear pump driving, and at the same time the side plates 218 and 218a. Although a part of the hydraulic oil on the high pressure side may be prevented from flowing into the low pressure side through the gap between the body 214 or the cover 216, there is another problem that the workability is remarkably deteriorated during the machining of the gear pump.

In addition, it is possible to effectively maintain the vacuum state by reducing the vertical machining error range of the bushing, and the development of the processing device of the hydraulic pump bushing to facilitate the mass production of the bushing has been continuously required.

Accordingly, the present invention is to solve the above problems, the object of the present invention is to simultaneously process the first body and the second body of the bushing facing each other, as well as to simultaneously process at least one or more bushings, Hydraulic pump bushing, which enables mass production according to the process, and the fixed bush is processed while the end mill is vertically raised, so that the margin of error of the vertical machining surface is small, making it easier to manage the clearance between the gear pump housing and the bushing installed in the housing. To provide a processing device.

In order to achieve the above objects, the present invention

A processing apparatus of a hydraulic pump bushing consisting of a cylindrical first body having a first through hole, a cylindrical second body having a second through hole, and a connection portion connecting the first body and the second body to each other,

Support means consisting of a plurality of vertical bars and horizontal bars;

Four guide rods erected vertically on the upper surface of the supporting means, the first and second fixed plates which are fixed to the guide rods and are spaced apart from each other, and are fitted up and down between the first and second fixed plates Working means including first and second moving plates;

A first rotating plate for machining all sides of the first body of the bushing and a second rotating plate for machining all sides of the second body of the bushing, wherein the first rotating plate and the second rotating plate are fixed to the first Rotating means rotatably installed on the plate;

A processing means including a pair of setting jigs, which are set up at the center of the first rotating plate and set at least one of the bushings, and a pair of processing jigs mounted on a surface of the second rotating plate and positioned to face each other; And

The main motor is provided to the support means, the power of the main motor is the power transfer means for moving the first jig plate, the first rotating plate and the second rotating plate in order to rotate the processing jig; Including,

The first rotating plate and the second rotating plate are achieved by providing a hydraulic pump bushing processing apparatus, each having a different radius of rotation with respect to each other.

Here, the setting jig is preferably provided with two bushings so as to be processed simultaneously.

The processing jig is first and second fixed blocks provided to face each other on the first rotating plate; First and second movable blocks slidably coupled to the first and second fixed blocks and fixedly coupled to a bottom surface of the first moving plate; An end mill fixture provided on the front surface of the first and second moving blocks; And it is preferable to include an end mill detachably installed in the end mill fixture.

The power transmission means is rotatably provided by a plurality of fixing brackets on an upper surface of the support frame immediately below the first fixing plate, and includes a driving gear and a second pulley on one side of the outer circumferential surface, wherein the first pulley and the second pulley are included. Pulley main rotating rod connected by the first connection belt; First and second crank shafts, each end of which is axially coupled to both ends of the main rotating rod, the other end of which is axially coupled to both ends of the second moving plate; A sub-rotary rod provided rotatably by a plurality of fixing brackets on an upper surface of the supporting means in a state parallel to the main rotating rod, and including a driven gear to be coupled to the main rotating rod; And a third pulley and a fourth pulley which are installed to stand on the support frame so as to cross the sub-spinning rod, and include a third pulley and a fourth pulley, and are provided with a third connection belt to be coupled to the third pulley and the first rotating plate to transmit rotational force, and a fourth pulley. And a vertical rotating rod having a fourth connection belt coupled to the second rotating plate to transmit rotational force; It is preferable to include.

The upper surface of the support means is preferably provided with a reduction means for reducing the rotational force of the main motor.

One end of the deceleration means is preferably provided with an initial setting handle for setting the processing jig to the initial position.

The deceleration means is provided on the outer circumferential surface of the sub rotary rod; And it is preferable to include a pinion provided on the vertical rotating rod to be gear-coupling with the rack.

A sliding guide jig is additionally provided on a bottom surface of the first moving plate, wherein the sliding guide jig includes: a guide jig body having a circular accommodating groove formed at a center thereof; A first slide slidably coupled by the first fixing bracket at one side of the receiving groove of the guide jig body; A second slide slidably coupled by the second fixing bracket at one side of the receiving groove of the guide jig body; And a first slide groove is formed at one side of the first fixing bracket, and a first slide protrusion is formed along a length direction so as to be fitted into the first slide groove at one side of the first slide. A second slide groove is formed on one side of the second fixing bracket, and a second slide protrusion is formed along the longitudinal direction on one side of the second slide so as to be fitted into the second slide groove.

Preferably, the first and second slides have a rotation range of 240 to 260 degrees.

According to the hydraulic pump bushing processing apparatus of the present invention, at least one bushing can be set in the setting jig of the first rotating plate, and the first body and the second body of the bushing can be simultaneously processed by the power of the main motor. As a result, the rapid processing of the corrosion is possible, thereby effectively performing mass production. In addition, the bushing allows the end mill of the processing jig to be processed vertically in a fixed state without moving to the setting jig, thereby reducing the upper and / or lower machining error range during the bushing operation, thereby providing a more effective function of the bushing. Has the effect of performing.

1 is a schematic view showing the internal configuration of a typical hydraulic pump;
2 is a photograph of a typical bushing;
3 is a photograph showing a state in which the bushing of FIG. 2 is installed in a storage chamber of a housing of a hydraulic pump;
Figure 4 is a full photograph of the hydraulic pump bushing processing apparatus according to an embodiment of the present invention;
5 is a photograph shown from the front of FIG. 4;
6 is a photograph shown from the right side of FIG. 4;
7 is an enlarged photograph showing main parts of the processing jig and the first and second rotating plates of FIG. 4;
FIG. 8 is a photograph showing an arrangement state of a main rotating rod, a sub rotating rod, and a second rotating plate in FIG. 4; FIG.
9 is a photograph showing a second crankshaft eccentrically coupled to the main rotating rod in FIG. 4;
10 is a photograph showing a machining process of a bushing fitted to a setting jig in FIG. 4;
11 is a photograph showing only the processing jig separated from FIG. 4;
12 is a photograph showing a state in which the bushing is processed by the processing jig of FIG.
13 to 15 are photographs showing the rotational state of the main gear and the driven gear in FIG. This is just after the driven gear is rotated, and Fig. 15 is a state in which the rotating projection of the main gear is completely separated from the gear part of the driven gear.
16 is a photograph showing a sliding guide jig in FIG. 4; And
17 is a photograph showing an enlarged state of the deceleration means in FIG. 4.

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

2 and 3, a storage chamber PH is formed in the hydraulic pump housing PH, and a bushing B is stored in the storage chamber PH. This bushing B comprises a cylindrical first body B2 having a first through hole B4. The bushing B also includes a cylindrical second body B6 having a second through hole B8. The connection part B9 connects the first body B2 and the second body B6 to each other. Bushing (B) is preferably in the shape of the Arabic numeral “8” as a whole.

4 to 6, the processing apparatus 100 of the hydraulic pump bushing according to the embodiment of the present invention includes a support frame 110 consisting of a plurality of vertical bars (110a) and horizontal bars (110b).

Working means are four guide rods 112 that are erected vertically on the upper surface of the supporting frame 110, the first and second fixing plates 114a and 114b which are fitted and fixed to the guide rods 112 and spaced apart from each other. ), The first and second moving plates 116a and 116b to be lifted and fitted between the first and second fixed plates 114a and 114b.

The rotating means includes a first rotating plate 120 for processing all sides of the first body B2 of the bushing B and a second rotating plate for processing all sides of the second body B6 of the bushing B ( 122, but the first rotating plate 120 and the second rotating plate 122 are rotatably installed on the first fixing plate 114a.

As long as the processing means is installed on the surface of the pair of setting jig 130 and the second rotating plate 122 in which the at least one bushing B is set in the center of the first rotating plate 120 and positioned opposite to each other. It includes a pair of processing jig. Here, the setting jig 130 may be provided with two bushings B to be processed simultaneously. The processing jig is slidably coupled to the first and second fixed blocks 136a and 136b and the first and second fixed blocks 136a and 136b provided on the first rotating plate 120 to face each other. The first and second moving blocks 138a and 138b fixedly coupled to the bottom surface of the first moving plate 116a, and the end mill fixture 139a provided on the front of the first and second moving blocks 138a and 138b. 139b). The end mill 139c is detachably installed at the end mill fixtures 139a and 139b.

The power transmission means is provided by the main motor 140 in the support frame 110. The power of the main motor 140 rotates the first rotating plate 120 and the second rotating plate 122 sequentially while elevating the first moving plate 116a. The main motor 140 is preferably installed in the support frame 110, but is not limited thereto. The first pulley 144a is rotatably protruded from the main motor 140.

The main rotating rod 144 is rotatably provided by a plurality of fixing brackets 148 on the upper surface of the support frame 110, which is positioned directly below the first fixing plate 114a. The second pulley 144b is provided on one side of the main rotating rod 144. The first connection belt 145 connects the first pulley 144a and the second pulley 144b. One end of the first and second crankshafts CS1 and CS2 is axially coupled to both ends of the main rotating rod 144 so as to be rotatable, and the other end is axially coupled to both ends of the second moving plate 116b, respectively. . The sub rotary bar 154 is rotatably provided by a plurality of fixing brackets 148 on the upper surface of the support frame 110 in a state parallel to the main rotary bar 144. The main gear 150 is provided on the main rotating rod 144. The driven gear 152 is provided on the sub rotating rod 154 to be geared to the main rotating rod 144.

Reduction means is preferably provided on the upper surface of the support frame 110 to reduce the rotational force of the main motor 140. The deceleration means includes a rack 146a and a pinion 154a. The rack 146a is provided to the sub rotary bar 154. The pinion 154a is provided to be in gear engagement with the rack 146a on the vertical rotating rod 156 which will be described later.

The vertical rotating rod 156 is installed standing on the support frame 110 so as to cross the sub rotating rod 154. The third pulley 156a and the fourth pulley 156b are horizontally provided upward and downward on the vertical rotating rod 156. The third connection belt 159a is coupled to the third pulley 156a and the first rotating plate 120 to transmit rotational force, and the fourth connecting belt 159b is the fourth pulley 156b and the second rotating plate 122. ) So that rotational force is transmitted.

Here, the rotation protrusion 150a protrudes from the outer circumferential surface of the main gear 150. On the outer circumferential surface of the driven gear 152, a gear portion 152a is formed to rotate intermittently by the rotation protrusion 150a of the main gear 150, and a rubber 152b is covered on the gear portion 152a. . This is because the rubber 152b can prevent the noise generated when the main gear 150 and the driven gear 152 is rotated in engagement with each other.

The first rotating plate 120 and the second rotating plate 122 have different turning radii with respect to each other. That is, it is preferable that the sliding guide jig 170 is further provided on the bottom surface of the first moving plate 116a. The sliding guide jig 170 is preferably formed in a disc shape, but is not limited thereto.

The sliding guide jig 170 has a guide jig body 172 in which a circular accommodating groove 172a is formed in the center, and a first fixing bracket 174 at one side of the accommodating groove 172a of the guide jig body 172. A first slide 178 slidably coupled by a second slide 180 that is slidably coupled by a second fixing bracket 176 at one side of the receiving groove 172a of the guide jig body 172. Include. At this time, a first slide groove 174a is formed at one side of the first fixing bracket 174, and a first slide protrusion 178a at one side of the first slide 178 to be fitted into the first slide groove 174a. Is formed along the longitudinal direction. Meanwhile, a second slide groove 176a is formed at one side of the second fixing bracket 176, and a second slide protrusion 180a is formed at one side of the second slide 180 so as to be fitted into the second slide groove 176a. It is formed along the longitudinal direction.

Here, it is preferable that the first and second slides 178 and 180 are inserted below the first and second fixing brackets 174 and 176 and have a rotation angle of about 240 to 260 degrees, but more preferably about 250 degrees. It is preferable to have a rotation angle of degrees.

The initial setting handle 158 is preferably provided at one end of the sub rotary bar 154 to set the processing jig to the initial position. Initial setting handle 158 preferably has a configuration capable of manual or automatic operation.

The air cylinder 160 is installed on the upper surface of the second fixing plate 114b and the shaft rod 162 is coupled to the front and the reverse. The tip of the shaft 162 is fixed to the first moving plate 116a. The second fixing plate 114b is fixed by pressing the bushing B mounted on the setting jig 130 by the shaft rod 162 of the air cylinder 160.

Hereinafter, the operation of the hydraulic pump bushing processing apparatus of the present invention with reference to the accompanying drawings in more detail.

Referring back to Figures 1 to 17, first, the operator rotates the initial setting handle 158 in the clockwise direction. In this way, the sub rotating rod 154 connected to the initial setting handle 158 is rotated together. At this time, the rack 146a of the sub rotary bar 154 is rotated together with the pinion 154a geared thereto. For this reason, while the vertical rotating rod 156 rotates, the 3rd pulley 156a and the 4th pulley 156b rotate together. Accordingly, the third connecting belt 159a of the third pulley 156a rotates the first rotating plate 120, while the fourth connecting belt 159b of the fourth pulley 156b rotates the second rotating plate 122. Rotate together By this process, the processing jig on the first rotating plate 120, that is, the first and second fixed blocks 136a and 136b are simultaneously rotated. By doing so, the end mill 139c is set to the initial machining position of the bushing B. FIG. Here, although the sub rotary bar 154 has been described as a manual operation by the initial setting handle 158, it can be automatically operated.

In this state, the setting jig 130 is fitted with a bushing B for processing. At this time, the setting jig 130 is preferably formed in a pair. In other words, the first through holes B4 and the second through holes B8 are formed in the first body B2 and the second body B6 of the bushing B, respectively. Here, the bushing (B) to be fitted to the setting jig 130 is preferably at least one to work, but is not limited thereto.

Then, when the operator turns on the air cylinder 160, the second moving plate 116b is lowered together with the shaft rod 162. As a result, the pressing rod 163 connected to the shaft bar 162 serves to fix the bushing b fitted to the setting jig 130 from the upper side so as not to move.

Subsequently, the operator drives the main motor 140. The driving force of the main motor 140 is to rotate the main rotating rod 144 by the first connection belt 145 of the first pulley 144a and the second pulley 144b. Here, the main rotating rod 144 transmits a rotational force to the first and second crankshafts CS1 and CS2 and the sub rotating rod 154.

First, the first and second crankshafts CS1 and CS2 allow the first moving plate 116a to move up and down along the guide rod 112. The first and second moving blocks 138a and 138b protrude downward from the bottom of the first moving plate 116a. For this reason, the lifting operation of the first moving plate 116a is that the first and second moving blocks 138a and 138b slide upward and downward from the first and second fixed blocks 136a and 136b. Accordingly, the bushings B set on the setting jig 130 are vertically processed by the end mills 139c fixedly installed on the end mill fixtures 139a and 139b of the first and second moving blocks 136a and 136b. It is.

Next, the main gear 150 of the main rotary rod 144 rotates the driven gear 152 of the sub rotary rod 154. At this time, the rotation protrusion 150a of the main gear 150 is intermittently rotated while being rotated together along the outer circumferential surface of the driven gear 152. This will be described in detail with reference to FIGS. 13 to 15. As shown in FIG. 13, the rotation protrusion 150a of the main gear 150 is in contact with the gear part 152a of the driven gear 152. As shown in FIG. 14, the rotation protrusion 150a of the main gear 150 is caught in the gear part 152a of the driven gear 152 to transmit rotational force. In other words, the driven gear 152 is rotated only in a state where the rotation protrusion 150a of the main gear 150 is caught by the gear portion 152a of the driven gear 152. Thereafter, as shown in FIG. 15, when the rotation protrusion 150a of the main gear 150 is separated from the gear part 152a of the driven gear 152, the driven gear 152 is not rotated and is stopped. To be. That is, the driven gear 152 is rotated only in a state in which the rotation protrusion 150a of the main gear 150 is in contact with the gear portion 152a of the driven gear 152.

Subsequently, the operation of the sub rotary bar 154 according to the rotation of the driven gear 152 rotates the vertical rotary bar 156 together by the combination of the rack 146a and the pinion 154a. The rack 146a of the sub rotary bar 154 is rotated together with the pinion 154a geared thereto. For this reason, while the vertical rotating rod 156 rotates, the 3rd pulley 156a and the 4th pulley 156b rotate together. Accordingly, the third connecting belt 159a of the third pulley 156a rotates the first rotating plate 120, while the fourth connecting belt 159b of the fourth pulley 156b rotates the second rotating plate 122. Rotate together By this process, the processing jig on the first rotating plate 120, that is, the first and second fixed blocks 136a and 136b are simultaneously rotated.

In summary, the first and second fixed blocks 136a and 136b are simultaneously rotated together with the first rotating plate 120. At the same time, the first and second moving blocks 138a and 138b installed on the first moving plate 116a are lifted and operated with respect to the first and second fixed blocks 136a and 136b. Here, the sliding guide jig 170 is provided between the first and second moving blocks 138a and 138b and the first moving plate 116a. In other words, the sliding guide jig 170 is coupled to the bottom surface of the first moving plate 116a. Upper ends of the first and second moving blocks 138a and 138b are slidably coupled to the sliding guide jig 170. That is, the first and second fixed blocks 136a and 136b together with the first rotating plate 120 are rotated, and the first and second moving blocks 138a and 138b coupled thereto are the sliding guide jig 170. It is coupled to the sliding rotation.

Here, the sliding guide jig 170 is a state in which the guide jig body 172 is fixedly coupled to the bottom surface of the first moving plate 116a. The first and second slides 178 and 180 are slidably coupled to the receiving grooves 172a of the guide jig body 172 by the first and second fixing brackets 174 and 176. The first and second slide protrusions 178a and 180a of the first and second slides 178 and 180 are the first and second slide grooves 174a and 176a of the first and second fixing brackets 174 and 176. Is inserted into the sliding guide. At this time, the rotation trajectories of the first and second slides 178 and 180 are rotated at different radii with respect to each other. That is, it is preferable that the first and second slides 178 and 180 are inserted below the first and second fixing brackets 174 and 176 and have a rotation angle of about 240 to 260 degrees, but more preferably about 250 degrees. It is preferable to have a rotation angle of degrees.

As a result, the first and second fixed blocks 136a and 136b are rotated together with the first rotating plate 120, and the first and second moving blocks 138a and 138b are sliding guides in the sliding guide jig 170. do. In this state, the bushing B set on the setting jig 130 on the first rotating plate 120 is rotated, and the end mill fixtures 139a and 139b of the first and second moving blocks 138a and 138b are rotated. It is processed vertically by the lifting operation of the end mill (139c) coupled to. When the machining operation of the bushing B is completed, the operator stops the operation of the main motor 140 to stop the lifting operation of the first and second crankshafts CS1 and CS2 and the first moving plate 116a. Let's do it.

Next, the shaft bar 162 is raised by the operation of the air cylinder 160 to raise the second moving plate 116b. In this state, the pressing hole 163 holding the bushing B of the setting jig 130 is also raised to release the pressed state of the bushing B. Subsequently, the worker pulls out the processed bushing B from the setting jig 130 to complete the machining operation. After that, the previous operation may be repeatedly performed for the machining operation of another bushing (B).

PH: hydraulic pump housing PH2: storage compartment
B: Bushing B2: First Body
B4: first through hole B6: second body
B8: second through hole B9: connecting portion
100: hydraulic pump bushing processing device
110: support frame 112: guide rod
114a, 114b: First and second fixed plates 116a, 116b: First and second moving plates
120: first rotating plate 122: second rotating plate
130: setting jig 134: processing jig
136a, 136b: first and second fixed blocks
138a, 138b: First and second moving blocks 139a, 139b: End mill fixture
140: main motor 144: main rotating rod
146: sub rotating rod 146a: rack
148: fixing bracket 150: driving gear
150a: rotary protrusion 152: driven gear
152a: gear portion 152b: rubber
154: sub rotating rod 154a: pinion
156: vertical rotating rod 156a, 156b: third, fourth pulley
158: Initial setting handle
160: air cylinder 162: shaft
170: sliding guide jig 172: guide jig body
172a: receiving groove 174,176: 1, 2 fixed bracket
174a, 176a: 1st, 2nd slide groove 178,180: 1st, 2nd slide 1
178a, 180a: 1st, 2nd slide projection

Claims (9)

A processing apparatus of a hydraulic pump bushing consisting of a cylindrical first body having a first through hole, a cylindrical second body having a second through hole, and a connection portion connecting the first body and the second body to each other,
Support means consisting of a plurality of vertical bars and horizontal bars;
Four guide rods erected vertically on the upper surface of the supporting means, the first and second fixed plates which are fixed to the guide rods and are spaced apart from each other, and are fitted up and down between the first and second fixed plates Working means including first and second moving plates;
A first rotating plate for machining all sides of the first body of the bushing and a second rotating plate for machining all sides of the second body of the bushing, wherein the first rotating plate and the second rotating plate are fixed to the first Rotating means rotatably installed on the plate;
A processing means including a pair of setting jigs, which are set up at the center of the first rotating plate and set at least one of the bushings, and a pair of processing jigs mounted on a surface of the second rotating plate and positioned to face each other; And
The main motor is provided to the support means, the power of the main motor is the power transfer means for moving the first jig plate, the first rotating plate and the second rotating plate in order to rotate the processing jig; , ≪ / RTI >
Hydraulic pump bushing processing apparatus, characterized in that the first rotating plate and the second rotating plate has a different radius of rotation with respect to each other. 2. The hydraulic pump bushing processing apparatus according to claim 1, wherein the setting jig is provided with two bushings simultaneously. The method of claim 2, wherein the processing jig
First and second fixed blocks provided on the first rotating plate to face each other; First and second movable blocks slidably coupled to the first and second fixed blocks and fixedly coupled to a bottom surface of the first moving plate; An end mill fixture provided on the front surface of the first and second moving blocks; And an end mill detachably installed at the end mill fixture. The method of claim 3, wherein the power transmission means
It is provided rotatably by a plurality of fixing brackets on the upper surface of the support frame directly below the first fixing plate, the main gear and the second pulley is included in one side of the outer peripheral surface, the first pulley and the second pulley first connection belt Main rotating rod connected by;
First and second crank shafts, each end of which is axially coupled to both ends of the main rotating rod, the other end of which is axially coupled to both ends of the second moving plate;
A sub-rotary rod provided rotatably by a plurality of fixing brackets on an upper surface of the supporting means in a state parallel to the main rotating rod, and including a driven gear to be coupled to the main rotating rod; And
It is installed standing on the support frame so as to cross the sub-spinning rod, and includes a third pulley and a fourth pulley, the third connection belt is provided to be coupled to the third pulley and the first rotating plate to transmit rotational force, and the fourth pulley and A vertical rotating rod having a fourth connection belt coupled to the second rotating plate to transmit rotational force; Hydraulic pump bushing processing apparatus comprising a. 5. The hydraulic pump bushing processing apparatus according to claim 4, further comprising a reduction means for reducing the rotational force of the main motor on an upper surface of the support means. 6. The hydraulic pump bushing processing apparatus according to claim 5, wherein an initial setting handle for setting the processing jig to an initial position is further provided at one end of the deceleration means. According to claim 6, The deceleration means is provided with a rack provided on the outer peripheral surface of the sub rotary rod; And a pinion provided to the vertical rotating rod to be able to engage the gear with the rack. According to any one of claims 1 to 3, The sliding guide jig is further provided on the bottom of the first movable plate,
The sliding guide jig is a guide jig body formed with a circular receiving groove in the center;
A first slide slidably coupled by the first fixing bracket at one side of the receiving groove of the guide jig body;
A second slide slidably coupled by the second fixing bracket at one side of the receiving groove of the guide jig body; , ≪ / RTI >
A first slide groove is formed at one side of the first fixing bracket, and a first slide protrusion is formed along a length direction to be fitted to the first slide groove at one side of the first slide, and one side of the second fixing bracket. The second slide groove is formed in the hydraulic pump bushing processing apparatus, characterized in that the second slide projection is formed along the longitudinal direction to be fitted to the second slide groove on one side of the second slide. 9. The hydraulic pump bushing processing apparatus according to claim 8, wherein the first and second slides have a rotation range of 240 to 260 degrees.

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