JP3450087B2 - Cylinder liner press-fit device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cylinder liner press-fitting device, and more particularly to a press-fitting device for press-fitting a cylinder liner into a cylinder block of an automobile engine.

[0002]

2. Description of the Related Art FIG. 16 shows an example of a conventional technique for press-fitting a cylinder liner into a cylinder block of an automobile engine.
Shown in. That is, conventionally, when the cylinder liner is press-fitted into the cylinder block, first, in the loading unit 100, the cylinder block 104 is placed on the free roller conveyor 102.
Put. Next, the cylinder block 104 is pushed and moved to the press-fitting process unit 106 located on the upstream side of the carry-in unit 100. In this press-fitting process unit 106,
First, the cylinder liner 108 is inserted into the bore portion of the cylinder on the tip end side of the cylinder block 104. After that, the press-fitting metal fitting (directly attached to the ram portion) 114 of the press-fitting jig portion attached to the ram portion 112 of the hydraulic press 110 is finely moved in the front-back direction by the cylinder block 104.
The cylinder liner 104 is engaged, and in this state, the work lifter 116 is lowered to mount the cylinder block 104 on the press bed 118, and the hydraulic press 110 press-fits the cylinder liner 108 into the bore portion of the cylinder block 104. After press-fitting, the work lifter 116 is lifted, and thereafter, the cylinder liners 108 corresponding to the other five cylinders are sequentially press-fitted one by one. At this time, the rack and pinion type table feed handle 120 is used.

After that, the unloading section 1 in which the cylinder block 104 in which the cylinder liner 108 is press-fitted is located on the upstream side
Push out to 22. At the carry-out section 122, a step between the upper end surface of the cylinder liner 108 and the upper surface of the cylinder block 104, which are press-fitted, is measured, and the quality of the press-fitted state is determined based on the value of the step. Specifically, for each cylinder, the operator measures the level difference at three locations equally divided in the circumferential direction by the dial gauge, and this measurement is performed for all six cylinders. At this time, if the variation between the cylinders exceeds the reference value, the cylinder liner of the cylinder that exceeds the reference value is removed, the cylinder block 104 is retracted to the press-fitting process unit 106, and the press-fitting operation is performed again. Was doing.

[0004]

However, in the above-mentioned prior art, the cylinder liner is press-fitted into several to several tens of cylinder blocks in a rod-producing manner, and then these are collectively determined to determine whether the press-fitted state is good or bad. As a result, the defective press-fitting was found to be delayed, and as a result, the press-fitting work had to be redone repeatedly, resulting in a significant decrease in work efficiency. Further, the quality of the press-fitted state is determined manually by the worker, and there is a request for automation to improve work efficiency. Therefore, the present invention has been made in order to solve the problems of the prior art, and a press-fitting device for a cylinder liner that improves work efficiency by making it possible to determine the quality of the press-fitting pressure and the press-fitting state during press-fitting work. It is intended to be provided. Another object of the present invention is to provide a cylinder liner press-fitting device that automates press-fitting work and improves work efficiency.

[0005]

In order to achieve the above object, the present invention provides a cylinder liner press-fitting device for press-fitting a cylinder liner into a bore portion of each cylinder of a cylinder block. Transfer means for moving to a position, positioning means for positioning the center of the bore portion at the predetermined press-fitting position, pressing means for press-fitting the cylinder liner into the bore portion of each cylinder at the positioned position, and this pressing means. Pressure measuring means for measuring the press-fitting pressure for a predetermined time, displacement sensor means for measuring steps of the press-fitted cylinder liner and cylinder block at a plurality of predetermined places, and press-fitting pressure and And a determining means for determining whether or not the press-fitted state is good.
In the cylinder liner press-fitting device of the present invention thus configured, the transfer means moves the cylinder block to a predetermined press-fitting position, and the positioning means positions the center of the bore portion of each cylinder of the cylinder block at this press-fitting position. Then, at this position, the pressing means press-fits the cylinder liner into the bore portion of each cylinder. At this time, the pressure measuring means measures the press-fitting pressure of the pressing means for a predetermined time.
Further, the displacement sensor means measures the step difference between the press-fitted cylinder liner and the cylinder block at a plurality of predetermined positions.
Based on the measured values of the pressure measuring means and the displacement sensor means, the determining means determines whether the press-fitting pressure and the press-fitting state are good or bad.

In the cylinder liner press-fitting device of the present invention, the transfer means locks a push lever on the rear end surface of the cylinder block, and the cylinder block is moved by the transfer hydraulic cylinder via the push lever. It is preferable to be provided as follows. In the cylinder liner press-fitting device of the present invention, it is preferable that the pressing means has a spherical seat and a spherical joint built in a ram portion having an aligning function. Also,
In the cylinder liner press-fitting device of the present invention, the positioning means includes a serrated indexing portion formed on the table portion on which the cylinder block is mounted, and an indexing pin that can be brought into close contact with the indexing portion. Positioning the center is preferred. In the cylinder liner press-fitting device of the present invention, it is preferable that the pressure measuring means is a load cell incorporated in a ram portion of the pressing means. Further, in the cylinder liner press-fitting apparatus of the present invention, it is preferable that the displacement sensor means measures the step at at least three positions in the circumferential direction. Further, in the present invention, the determining means determines that the press-fitting pressure is good when the value of the press-fitting pressure is within a predetermined range, and determines that the press-fitting pressure is not good when the value of the press-fitting pressure is outside the predetermined range, and determines the maximum difference in level between the plurality of locations. When the difference between the value and the minimum value is within the predetermined range, it is preferable to determine that the press-fitted state is good, and when it is outside the predetermined range, it is preferable to determine that the press-fitted state is no.

Further, in the present invention, it is preferable that the cylinder block is a cylinder block of an in-line multi-cylinder engine.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a cylinder liner press-fitting apparatus of the present invention will be described below with reference to the accompanying drawings. Figure 1
FIG. 2 is a front view showing the overall configuration of an embodiment of a cylinder liner press-fitting device of the present invention, and FIG. 2 is a plan view of FIG. As shown in FIGS. 1 and 2, reference numeral 1 denotes a cylinder liner press-fitting device, and the cylinder liner press-fitting device 1 is
It is configured as follows. That is, the setup station A, the positioning station B, the press-fitting station C, and the unloading station D are sequentially arranged from the downstream loading side to the upstream unloading side. First, in the setup station A, a series 6 is installed on the free roller conveyor 2.
A cylinder block 4 of a cylinder engine is mounted.
As shown in FIG. 3, the cylinder liner 6 has a temporary insertion portion 6 whose diameter is reduced by a predetermined value at its lower end.
The temporary insertion portion 6a of the cylinder liner 6 having a is inserted into the bore portion of each cylinder of the cylinder block 4 and is in the temporary placement state as shown in FIG. Next, at this setup station A, the operator moves the cylinder block 2 on which the cylinder liner 4 is temporarily placed to the next positioning station B.
Push into. As a result, automation after the positioning station B is executed.

Next, in the positioning station B,
A top roller conveyor 8 is provided. For this reason,
The tip portion of the cylinder block 4 which is the work is 1 in FIG.
When it hits the top roller 10 located on the right side, the top roller 10 stops rotating due to the weight of the cylinder block 4, and the cylinder block 4 and the chain 12 start moving leftward in FIG. The process proceeds until the tip portion of the end stopper 14 arranged at the rear end portion comes into contact with the end stopper 14. When the tip end of the cylinder block 4 comes into contact with the end stopper 14, the top roller 10 rotates with the cylinder block 4 as the chain 12 advances, and the tip end of the cylinder block 4 ends up.
Accurate positioning is performed in the state of being in contact with 4. In addition,
The end stopper 14 can be moved up and down by a hydraulic cylinder 16. Next, the press-fitting station C will be described. In this press-fitting station C, a hydraulic press 18
4 is provided, only the structural parts to which pressure is applied by the hydraulic press 18 are shown for easy understanding. That is, a bed portion 20 is provided below the hydraulic press 18, a table base portion 22 is arranged on the bed portion 20, and the table base portion 22 is further provided.
A table portion 24 is arranged on the top. Further, a conveyor unit 26 is arranged on the table unit 24, and the cylinder block 4 which is a work is mounted on the table unit 24. Further, a work shift hydraulic cylinder 28 for shifting the work in the traveling direction is provided inside the table base portion 22, while the conveyor portion 26 is moved in the table portion 24 in the vertical direction. A work lift cylinder 30 for lifting a work is built in.

The press-fitting station C is further provided with a transfer device 32, as shown in FIGS. 6 and 7. The transfer device 32 carries out the work whose press-fitting work has been completed at the press-fitting station C to the carry-out station D, and when the table portion 24 becomes empty after the carry-out, is positioned at the positioning station B by the end stopper 14 and stands by. This is a device for pulling the next work to be inserted into the press-fitting station C. At this time, the end stopper 14 is lowered by the hydraulic cylinder 16, and the work is pulled to a position where the cylinder liner 6 is press-fitted into the bore portion of the first cylinder of the cylinder block 4. The transfer device 32 enables accurate positioning to the center of the bore. The transfer device 32 is configured as follows. That is, as shown in FIGS. 6 and 7, the transfer table 3 is placed at a predetermined position.
4 are arranged, and a plurality of V rollers 36 are provided on the transfer table 34 along the work advancing direction. On the other hand, a transfer hydraulic cylinder 38 is fixedly arranged, and the transfer hydraulic cylinder 38 includes a cylinder rod 39 extending in the work advancing direction. A transfer bar 40 is mounted on the V-roller 36, the rear end of which is connected to the cylinder rod 39 via a connecting fitting 41 so as to be rotatable in the circumferential direction. The transfer bar 40 has a predetermined position. A push lever 42 that is capable of contacting the rear end surface 4a of the cylinder block 4 is fixedly attached to the workpiece side. This push lever 42, as shown in FIG.
1st for pushing work from press into station C
Push lever 42a and work are pressed into station C
And a second push lever 42b for pushing it out to the carry-out station D. Further, a shift bar 44 is provided which extends in parallel with the transfer bar 40 and whose both ends and an intermediate portion are integrally fixed to the transfer bar 40 via a shift lever 43. Further, a shift unit portion 46 for vertically shifting the shift bar 44 is provided at a predetermined position. The shift unit portion 46 is composed of a shifter 48 for accommodating and engaging the shift bar 44 in the recess 48a thereof, and a shifter hydraulic cylinder 50 for vertically moving the shifter 48.

The transfer device 32 operates as follows. That is, when the work is carried out to the carry-out station D and the table section 24 becomes empty, the cylinder rod 39 is pushed out toward the positioning station B by the transfer hydraulic cylinder 38, whereby the transfer bar 40 and the shift bar 44 are moved. Both move to a predetermined position in the direction of the positioning station B. At this predetermined position, the shifter hydraulic cylinder 50 is operated to raise the shifter 48 to the position shown in FIG. 7, whereby the shift bar 44 rises and the transfer bar 40 rotates via the shift lever 43, and the final position is reached. Push lever 4
2 (42a) rotates from the position shown by the chain line in FIG. 7 to the position shown by the solid line. As a result, the push lever 42a is engaged with the rear end surface 4a of the cylinder block 4, which is the work. After this, with the push lever 42a engaged with the rear end surface 4a of the cylinder block 4, the cylinder rod 39 can be pushed toward the press-fitting station C by the transfer hydraulic cylinder 38 this time. In this way, the cylinder block 4 moves from the positioning station B to the press-fitting station C. At this time, the cylinder block 4 moves to a position where the cylinder liner 6 is press-fitted into the bore portion of the first cylinder, and the positioning at the center of the bore can be performed accurately.

Next, a device for positioning the cylinder block 4 at the center of the bore of each cylinder in the press-fitting station C will be described with reference to FIGS. The cylinder block 4 moves from the positioning station B to a predetermined position of the press-fitting station C by the transfer device 32, and then stops at that position. In this state, the bush lever 42 jumps upward and is disengaged from the cylinder block 4 which is a work (shown by a chain line in FIG. 7). Further, as shown in FIG. 8, the work lift hydraulic cylinder 30 operates and the conveyor unit 26 descends from the position y _{1 to} the position y ₂ (moving distance δ). At this time, the cylinder block 4, which is a work, also descends, and the table portion 2
4 to contact the work receiving portion 24a. In this state, in order to allow the work to be seated on the table portion 24, the locate pin 52 is fitted into the knock holes 54 provided at four positions on the lower surface of the cylinder block 4 by the hydraulic cylinder (not shown) provided in the work receiving portion 24a. Insert and fix the work position. Further, in order to confirm the seating of the work, a pressure sensor 56 is provided on the work receiving portion 24a, and the lower surface of the work and the work receiving portion 24 are provided by the pressure sensor 56.
Air leakage with a is detected, and seating confirmation is performed. In this way, the cylinder block 4 is integrally supported by the table portion 24, the table base portion 22 and the hydraulic press bed portion 20 so as to withstand the applied pressure.

As shown in FIGS. 9 and 10, the table portion 24 is slidable on the table base portion 22 by a work shift hydraulic cylinder 28 and movable in the work advancing direction. An indexing plate portion 60 is integrally provided on one surface side of the table portion 24 along the traveling direction. This index plate 6
A positioning sensor 62 for positioning the cylinder block 4 at the center of the bore of each cylinder at a predetermined position facing 0.
Are arranged. The positioning sensor 62 includes a forward end detection sensor 62a, a backward position detection sensor 62b, a press-fitted position detection sensor 62c, a deceleration start command sensor 62d, and an index pin lift command sensor 62e. In addition, at a predetermined position on the surface of the indexing plate portion 60 corresponding to each of the sensors 62a to 62e, a convex detection member 64 is provided.
Is provided. The detection member 64 includes a forward end detection member 64a, a retracted position detection member 64b, a press-fitted position detection member 64c, a deceleration start command member 64d, and an index pin lift command member 64e. Further, the index plate portion 6
A saw-toothed index portion 66 is formed at the lower end portion of 0. An indexing hydraulic cylinder 68 is arranged at a predetermined position below the indexing portion 66, and the indexing hydraulic cylinder 68 is disposed.
This causes the indexing pin 70 to move in the vertical direction. A contact confirmation sensor 72 is provided at the upper end of the indexing pin 70. Further, the index pin extraction sensor 74 that detects that the index pin 70 is moving upward and the index pin return sensor 7 that detects that the index pin 70 is moving downward.
6 is provided.

Here, the forward end detecting sensor 62a and the forward end detecting member 64a are pressed into the cylinder liner 6 into the bores of all the cylinders of the cylinder block 4 by advancing the table portion 24 leftward in FIG. It is for detecting the forward end position where the press-fitting is completed. The backward position detecting sensor 62b and the backward position detecting member 6
4b indicates the backward end position of the table portion 24 when the table portion 24 is moved backward to the positioning station B side (right side in FIG. 10) after the press-fitting is completed in all cylinders and the cylinder block 4 is pushed out to the carry-out station D. It is for detection. Press fit position detection sensor 62
c and the press-fitting position detection member 64c indicate that the table portion 24 has reached the position corresponding to the bore center of each cylinder while the table portion 24 is moving in the traveling direction by the work shift hydraulic cylinder 28. It is for detection. Deceleration start command sensor 62d and deceleration start command member 6
4d is a work shift hydraulic cylinder 28 before the table portion 24 reaches the position corresponding to the center of the bore of each cylinder.
This is for decelerating the movement of the table section 20 due to. The index pin lift command sensor 62e and the index pin lift command member 64e move the index pin 70 upward before the table portion 24 reaches the position corresponding to the bore center of each cylinder to move the index pin 70 upward. It is for abutting on one side surface. The contact confirmation sensor 72 includes the indexing pin 70 and the indexing portion 6.
This is for confirming the close contact of one side surface of No. 6. In this way, since the indexing pin 70 and one side surface of the indexing portion 66 are in close contact with each other, the center of the bore can be accurately positioned.

Next, a method of press-fitting the cylinder liner 6 into the bore portion of each cylinder in the hydraulic press 18 and the press-fitting station C will be described with reference to FIGS. 11 to 13. A ram portion 80 is connected to the tip of the hydraulic press 18, and a load cell holding frame 82 is fixed to the lower side of the ram portion 80. A load cell 84 for detecting press-fitted pressure is housed in the load cell holding frame 82, and a load cell presser 86 is in contact with the load cell 84 and is held by the load cell holding frame 82 at the lower end portion of the load cell 84. . On the lower outer periphery of the load cell presser 86,
The joint fitting 88 is fixed. A spherical seat 90 having a centering function and a spherical joint 92 are housed inside the load cell presser 86, and a press-fitting metal fitting 94 for press-fitting the cylinder liner 6 is fixed to the lower end of the spherical joint 92. ing. At predetermined positions on the lower end of the outer periphery of the press-fitting fitting 94, three displacement sensors 96 are arranged at equal intervals in the circumferential direction.
(See FIG. 13) is attached. As described above, in the present embodiment, the center of the bore of each cylinder is accurately positioned by using the above-described indexing plate portion 60, the indexing pin 70, etc., and the spherical seat 90 and the spherical joint 92 provide the centering function. ,
With the hydraulic press 18, the cylinder liner 6 can be press-fitted extremely easily without difficulty.

As shown in FIG. 14, the press-fitting pressure of the hydraulic press 18 into the bore portion of the cylinder block 4 of the cylinder liner 6 is a predetermined time after the measurement start time (A) which is the press-fitting start. When a certain measurement is completed (C)
Is measured up to. If the value of the press-fitting pressure at the time of completion of the measurement (C) is within the OK range, it is determined that the press-fitting pressure is "OK", and if it is outside the OK range, the press-fitting pressure is "NO". To determine. In addition, the displacement sensor 96 causes displacements at three positions, that is, the cylinder block 4
The step between the upper end surface of the cylinder and the cylinder liner 6 is measured. When all of the measured values of the steps of the three places are within the predetermined range, and the difference between the maximum value and the minimum value of the steps of the three places is the value within the predetermined range. In this case, the press-fitted state is determined to be “OK”, and on the other hand, if any of the measured values of the three steps is out of a predetermined range, or if the values of the three steps are When the difference between the maximum value and the minimum value is outside the predetermined range, it is determined that the press-fitted state is “No (NG)”. In this manner, the hydraulic press 18 sequentially press-fits the cylinder liner 6 into the bore portion of each cylinder of the cylinder block 4, and determines the press-fitting pressure and the press-fitting state for each cylinder. As described above, according to this embodiment, the press-fitting pressure and the press-fitting state are determined every time the cylinder liner 6 is press-fitted into the bore portion of one cylinder, so that the press-fitting abnormality of the cylinder liner is immediately detected. be able to.

After the cylinder liner 6 is press-fitted in the press-fitting station C in this manner, the work lift hydraulic cylinder 30 is actuated to move the conveyor section 26 from the position y _{2 to} the position y ₂ as shown in FIG. _The cylinder block 4 which is the work is lifted to the position ₁ and mounted on the conveyor unit 26. After that, the transfer device 32 shown in FIG. 6 is operated to engage the second push lever 42 with the rear end surface 4a of the cylinder block 4, and the transfer hydraulic cylinder 38 moves the cylinder rod 39 to the unloading station D.
Can be pushed in the direction of. In this way, the cylinder block 4 for which the press-fitting work has been completed is pushed out from the press-fitting station C to the unloading station D. Next, the operation of this embodiment will be described with reference to the flowchart shown in FIG. In this flowchart, S represents each step. First, S1
1, after the work is pushed from the setup station A into the positioning station B, the work is advanced on the positioning station B in the leftward direction in FIG. next,
In S2, it is determined whether or not the work has reached the traveling end. Specifically, it is determined whether or not the front end of the cylinder block 4, which is a work, has come into contact with the end stopper 14. When not in contact, the process returns to S2, and when in contact, the process proceeds to S3. In S3, the transfer device 32 is operated.

Next, in S4, it is determined whether or not the bore portion of the first cylinder has reached a predetermined position. If the predetermined position is reached, the work is lowered by the work lift hydraulic cylinder 30 in S5 (see FIG. 8). Next, in S6, the work is fixed by the locate pin 52. Thereafter, in S7, seating confirmation is performed by the pressure sensor 56. Then, in S8, the indexing pin 70 and the like described above are used to perform positioning so as to be the center of the bore portion of the first cylinder. Next, in S9, the ram portion 80 of the hydraulic press 18 is lowered to start the press-fitting work. At this time, in S10, the load cell 8
The measurement of the press-fitting pressure is started by 4. After that, in S11, it is determined whether or not the value of the press-fit pressure when a predetermined time (t) has elapsed after the start of measurement is within the OK range shown in FIG. If it is within the OK range, in S12, OK
Display and store. On the other hand, if it is outside the OK range, S1
In 3, the NG display and storage are performed. In this way, in S12 and S13, the OK / NG determination (good / bad determination) of the press-fitting pressure is performed. Next, in S14, the descent of the ram portion 80 of the hydraulic press 18 is stopped. After this, S1
In step 5, the displacement sensor 96 measures one step, and in step S16, the step measurement is repeated until it is determined that the three steps have been measured. From now on, in S17, the above-mentioned OK / NG determination of the press-fitted state is performed. Then, in S18, the ram portion 80 is raised. Next, in S19, the table portion 24 is slightly retracted, and S
At 20, the index pin 70 is turned off to lower it, and at S21, the table portion 24 is moved forward by the bore pitch (one bore).

Thereafter, in S22, the table portion 20
Is determined at the forward end by the forward end detection sensor 62a and the forward end detection member 64a. If it is not the forward end, the process returns to S8 and the press-fitting work from the second cylinder to the fifth cylinder is executed. In the case of the forward end, it means that it is located in the bore portion of the sixth cylinder, so the routine proceeds to S23,
By executing the contents of S8 to S20, the work of press-fitting the cylinder liner into the bore portion of the sixth cylinder is completed.

[0020]

As described above, according to the press-fitting device for a cylinder liner of the present invention, it is possible to determine the quality of the press-fitting pressure and the press-fitting state during the press-fitting work, and the work efficiency is improved. According to the present invention, press-fitting work is automated and work efficiency is improved.

[Brief description of drawings]

FIG. 1 is a front view showing the overall configuration of an embodiment of a cylinder liner press-fitting device of the present invention.

FIG. 2 is a plan view of FIG.

FIG. 3 is a partial cross-sectional view showing a temporary insertion portion at a lower end portion of a cylinder liner.

FIG. 4 is a front view showing a part of a press-fitting station in an embodiment of the press-fitting device for a cylinder liner of the present invention.

5 is a side view of FIG.

FIG. 6 is a front view showing a transfer device in a press-fitting station in one embodiment of the press-fitting device for a cylinder liner of the present invention.

7 is a side view of FIG.

FIG. 8 is a side view for explaining the vertical movement of the table portion in the press-fitting station in the embodiment of the press-fitting device for the cylinder liner of the present invention.

FIG. 9 is a side view for explaining the positioning of the bore portion in the center of the press-fitting station in the embodiment of the press-fitting device for the cylinder liner of the present invention.

FIG. 10 is a front view for explaining the positioning of the bore portion in the center of the press-fitting station in the embodiment of the press-fitting device for the cylinder liner of the present invention.

FIG. 11 is a cross-sectional view showing a ram portion of a hydraulic press in a press-fitting station in an embodiment of the press-fitting device for a cylinder liner of the present invention.

12 is a partially enlarged sectional view of FIG.

FIG. 13 is a plan view showing a mounting position of a displacement sensor in a press-fitting station in one embodiment of the cylinder liner press-fitting apparatus of the present invention.

FIG. 14 is a diagram showing a relationship between press-fitting pressure and time at a press-fitting station in one embodiment of the cylinder liner press-fitting apparatus of the present invention.

FIG. 15 is a flowchart for explaining the operation of an embodiment of the cylinder liner press-fitting device of the present invention.

FIG. 16 is a front view showing the overall configuration of a conventional cylinder liner press-fitting device.

[Explanation of symbols]

1 Cylinder liner press-fitting device 4 cylinder block 6 Cylinder liner 18 hydraulic press 22 Table base 24 table section 26 Conveyor section 28 Work shift hydraulic cylinder 30 Work Lift Hydraulic Cylinder 32 Transfer device 34 Transfer stand 36 V roller 38 Hydraulic cylinder for transfer 39 Cylinder rod 40 Transfer Bar 42 Push lever 43 Shift lever 44 shift bar 46 Shift unit section 48 shifters Hydraulic cylinder for 50 shifter 60 Index plate 62 Positioning sensor 64 Detection member 66 Index 68 Indexing hydraulic cylinder 70 Index pin 72 Adhesion confirmation sensor 80 Ram 84 load cell 86 Load cell press 90 Spherical seat 92 spherical joint 94 press fitting 96 displacement sensor

Continuation of front page (56) References JP-A-8-39365 (JP, A) JP-A-5-38636 (JP, A) JP-A-5-261628 (JP, A) JP-A 1-246025 (JP , A) JP 1-199734 (JP, A) JP 61-203237 (JP, A) Actual opening 3-15035 (JP, U) Actual opening 2-78228 (JP, U) Actual opening 63-179028 (JP, U) Actual development Sho 62-121044 (JP, U) (58) Fields surveyed (Int.Cl. ⁷ , DB name) B23P 19/00-21/00 F02F 1/00 F02F 1 / 08

Claims (8)

(57) [Claims] 1. A cylinder liner press-fitting device for press-fitting a cylinder liner into a bore portion of each cylinder of a cylinder block, wherein transfer means for moving the cylinder block to a predetermined press-fitting position, and a center of the bore portion at the predetermined press-fitting position. Positioning means for positioning, a press means for press-fitting the cylinder liner into the bore portion of each cylinder at the positioned position, a pressure measuring means for measuring the press-fit pressure of the press means for a predetermined time, and a press-fitted cylinder liner. Displacement sensor means for measuring the steps of the cylinder block at a plurality of predetermined locations, and determination means for determining whether the press-fitted pressure and the press-fitted state are good or bad based on the measured values of the pressure measuring means and the displacement sensor means. Cylinder liner press-fitting device. 2. The transfer means is provided so that a push lever is locked to a rear end surface of the cylinder block, and the cylinder block is moved by a transfer hydraulic cylinder via the push lever. Item 1. A cylinder liner press-fitting device according to Item 1. 3. The press-fitting device for a cylinder liner according to claim 1, wherein the pressing means has a spherical seat and a spherical joint built in a ram portion having a centering function. 4. The positioning means positions the center of the bore portion by means of a saw-toothed indexing portion formed on a table portion on which the cylinder block is mounted and an indexing pin that can be brought into close contact with the indexing portion. The cylinder liner press-fitting device according to claim 1. 5. The cylinder liner press-fitting device according to claim 1, wherein the pressure measuring means is a load cell incorporated in a ram portion of the pressing means. 6. The press-fitting device for a cylinder liner according to claim 1, wherein the displacement sensor means measures a step at at least three positions in the circumferential direction. 7. The determination means determines that the press-fitting pressure is good when the value of the press-fitting pressure is within a predetermined range and determines that the press-fitting pressure is not good when the value of the press-fitting pressure is outside the predetermined range, and determines the maximum value of the steps at the plurality of locations. The press-fitting device for a cylinder liner according to claim 1, wherein the press-fitting state is determined to be good when the difference between the minimum value and the minimum value is within a predetermined range, and is determined to be no when the difference is outside the predetermined range. 8. The press-fitting device for a cylinder liner according to claim 1, wherein the cylinder block is a cylinder block of an in-line multi-cylinder engine.