Packerhead and core control system

A concrete pipe making machine having a packerhead vibrating core and a control for automatically controlling the movement of the packerhead and core relative to each other as the packerhead and core move up and down within a mold to form a concrete pipe. The control has valve units operable to restrict the flow of hydraulic fluid supplied to the hydraulic control cylinders which control the movements of the packerhead and core.

SUMMARY OF INVENTION 
The invention is directed to a control means for controlling the operation 
of a packerhead and vibrating core concrete pipe making machine. The 
control means functions to automatically position the core immediately 
behind the packerhead during the forming of the pipe in the mold. A 
packerhead pipe making machine has a rotating packerhead carried by a 
cross head. Hydraulic cylinder means operate to move the cross head in a 
vertical direction to thereby move the packerhead along the longitudinal 
upright axis of a mold used to make concrete pipe. A secondary 
densification unit is used with the packerhead machine to redensify the 
concrete pipe and relieve the stress on the cage. The secondary 
densification unit includes an upright cylindrical core carrying a 
vibrator. Hydraulic cylinder means operate to move the core up into the 
mold behind the packerhead. As soon as the core has gone through the pipe, 
it is withdrawn by the withdrawal action of the hydraulic cylinder means. 
The packerhead moves down with the core until the core is out of the bell 
end of the pipe. The packerhead is then raised through the pipe to enable 
the turntable to be rotated placing the complete pipe at the offbearing 
station. A new form with a steel cage is carried by the turntable to the 
production station in vertical alignment with the packerhead and core. 
The control means of the invention functions to regulate the flow of 
hydraulic fluid to the packerhead moving hydraulic cylinder means and the 
core moving hydraulic cylinder means in a manner which maintains a 
predetermined distance between the top of the core and the bottom of the 
packerhead during both the upward and downward movements of the core and 
packerhead. The control means is a structural and hydraulic fluid 
arrangement that automatically coordinates the relative movement between 
the packerhead and core to insure a small space between adjacent parts of 
the packerhead and core during the concrete pipe making process. The 
separation of the core isolates the packerhead from the vibrations of the 
core. This removes vibration forces from the packerhead support and drive 
structure. The packerhead rotates independently of the core. Also, the 
core is vibrated without dampening by the packerhead.

DESCRIPTION OF PREFERRED EMBODIMENT 
Referring to FIG. 1, there is shown a concrete pipe making machine commonly 
known as a secondary densification unit indicated generally at 10. Machine 
10 has a framework indicated generally at 11 attached to a base or support 
12, such as a concrete foundation. Frame 11 includes a pair of spaced 
upright posts or I beams 13 and 14. The upper ends of beams 13 and 14 are 
connected with a top cross member 16. Intermediate portions of beams 13 
and 14 are connected to a horizontal cross member 17. 
A cross head indicated generally at 18 is movably supported on a pair of 
upright cylindrical guides 19 and 21. The upper ends of guides 19 and 21 
are connected to top cross member 16. The lower ends of guides 19 and 21 
are connected to the cross member 17. Cross head 18 has sleeves 22 
containing suitable bearings for slidably mounting cross head 18 on guides 
19 and 21 to permit cross head 18 to be moved in an up and down direction. 
Cross head 18 has a transverse base 23 supporting a power transmission or 
gear box 24. An electric motor 26 is drivably connected to gear box 24 to 
rotate a downwardly directed packerhead shaft 27. Shaft 27 supported on 
the bottom of gear box 24 is located within a tubular housing or sleeve 
28. 
A packerhead indicated generally at 29 is secured to the lower end of shaft 
27. Packerhead 29 has a circular plate or disc 31 rotatably supporting a 
plurality of rollers 32. A cylindrical wall or flange 33 extends 
downwardly from rollers 32. Upwardly extended radial paddles or blades 34 
are attached to the top of plate 31. Paddles 34 can be attached to the 
upper surface of rollers 32. Paddles 34 rotate with disc 31 to move 
concrete into the annular space between the packerhead 29 and mold 43. 
Cross head 18 and packerhead 29 are moved up and down with a pair of 
elongated hydraulic cylinders 36 and 37. Cylinder 36 has a base or bottom 
end mounted on a bracket 38 secured to post 31. The lower end of cylinder 
37 is attached to a bracket 39 secured to post 14. Each cylinder 36 and 37 
can be replaced with a pair of upright piston and cylinder assemblies. 
A circular turntable 41 is movably mounted on base 12 for rotation about 
post 14. A power unit 42, such as a motor and gear drive structure, 
operates to sequentially rotate turntable 41 to locate a pipe jacket or 
mold 43 in a production station in vertical alignment with packerhead 29. 
Mold 43 has a bell or lower end surrounding a pallet 44 resting on top of 
turntable 41. Pallet 44 can be mounted on a pallet positioner secured to 
turntable 41. 
A top table 47 is located above mold 43. Top table 47 can be constructed 
with a cone-shaped member 48 and movable wiper blades (not shown) for 
directing concrete into the top of mold 43. An example of a top table is 
shown in U.S. Pat. No. 3,551,968. Top table 47 is mounted on a pair of 
upright tubular members or guides 48 and 49. The lower ends of guides 48 
and 49 are mounted on brackets 38 and 39, respectively. The upper ends of 
the guides 48 and 49 are attached to cross frame member 17. Hydraulic 
cylinders (not shown) are attached to top table 47 and frame member 17 for 
raising the top table off the top of mold 43 so that mold and pipe 46 
therein can be moved with turntable 41 to an unloading or off bearing 
position. A conveyor 51 located adjacent the top of turntable 47 is 
operable to move concrete from a storage area, such as a hopper, and 
deliver the concrete to the top table and discharge concrete into mold 43 
on top of packerhead 29. 
A vibrating core assembly indicated generally at 52 is located below 
turntable 41 in longitudinal alignment with packerhead 29. Core assembly 
52 has an elongated cylindrical sleeve or core 53 having a head or closed 
top end 54. End 54 is located immediately below packerhead 29. The control 
system of the invention is operable to maintain a minimum distance or 
clearance between head 54 and the lower part of packerhead 29 during the 
formation of pipe 46. A hydraulic vibrator 56 located within core 53 is 
mounted on transverse support structures secured to the cylindrical walls 
of core 53. The hydraulic vibrator 56 located within core 53 is mounted on 
transverse support structures secured to the cylindrical walls of core 53. 
The hydraulic vibrator 56 can be the vibrator disclosed in U.S. Pat. No. 
3,948,354. 
A plurality of downwardly directed legs 57 attached to a base 58 connect 
the lower end of core 53 to an extractor table or platform 59. Platform 59 
is a support or mount member for core 53. Upright sleeves 60 and 61 
secured to opposite sides of platform 59 are slidably mounted on upright 
cylindrical rods or guides 62 and 63. Guides 62 and 63 are mounted on a 
horizontal base frame 64 and horizontal top frame 66. Frame 66 is part of 
the framework for the core assembly and a bell packer indicated generally 
at 68. A pair of elongated downwardly extended hydraulic cylinders 67 
secured to the center portion of platform 49 function to move the platform 
59 and core 63 in a vertical direction in conjunction with the vertical 
movement of packerhead 29. The control system includes means to control 
the hydraulic fluid under pressure to cylinders 67 and thereby control the 
up and down movement of the core 53 while maintaining a close clearance 
between core head 54 and the bottom of packerhead 29. 
Bell packer 68 is operable to raise, rotate, and vibrate pallet 44 to 
finish and densify the concrete in the bell end of mold 43 during the 
initial stages of the forming of pipe 46. Bell packer 68 includes an 
annular frame 69 surrounding core 53. Frame 69 is movably mounted on a 
pair of upright guides or rods 73 and 74 with sleeves 71 and 72. Hydraulic 
cylinders (not shown) are used to raise the annular frame 69 to locate a 
rotatable ring 77 in driving engagement with pallet 44. A drive unit 78, 
including a hydraulic motor, is used to rotate the ring 77 whereby pallet 
44 rotates relative to the concrete in the bell end of the pipe. This 
finishes and minimizes voids in the concrete in the bell end of the pipe. 
The guides 73 and 74 are mounted on cross frame member 76 and the top 
frame member 66. An example of a bell packer structure is shown in 
Applicant's U.S. Patent application Ser. No. 753,526, filed Dec. 22, 1976, 
now U.S. Pat. No. 4,118,165. Other types of bell packer structures can be 
used to rotate and vibrate the pallet 44. 
Referring to FIG. 7, there is shown the control arrangement for the cross 
head cylinders 36 and 37 and core cylinders 67. The control arrangement 
has a hydraulic fluid system 79 including a pump unit 81 connected to a 
reservoir 82 with an inlet line 83. Pump unit 81 delivers fluid under 
pressure to an outlet line 86. Pump unit 81 can be a pump driven by an 
electric motor operable to deliver 60 gpm at 1,000 psi. Other types of 
pumps can be used to deliver hydraulic fluid under pressure to line 86. 
Line 86 is connected to a valve assembly 84. Valve assembly 84 is 
connected with a return line 87 to reservoir 82. Valve assembly 84 has a 
central neutral position to block the flow of fluid to lines 88 and 89 
connected to opposite ends of the cross head cylinders 36 and 37. Valve 
assembly 84 has a first position to direct the hydraulic fluid to the 
upper or rod end of the cylinders 36 and 37 and allow fluid to flow from 
the lower or head end of the cylinders back to reservoir 82 and a second 
position which reserves the flow of hydraulic fluid to and from cylinders 
36 and 37. Valve assembly 84 has control solenoids 84A operable to control 
its operating positions. 
A control valve 90 is located in line 89. Control valve 90 has a restricted 
flow throat or passage 90A connected to a line or hose 91 carrying supply 
control hydraulic fluid to valve 90. The flow of hydraulic fluid through 
passage 90A is restricted with a movable plunger operated with the control 
hydraulic fluid. Line 91 carrying the control hydraulic fluid leads to 
first control valve 121 hereinafter described. Valve 90 has a one-way 
check valve 90B allowing unrestricted flow of fluid to the head ends of 
cylinders 36 and 37 and restricting return flow of fluid therefrom. Return 
flow must flow through passage 90A so that the rate of flow of return 
hydraulic fluid through passage 90A controls the speed of the down 
operation of cylinders 36 and 37. 
A line 92 is connected to the pump output and a second solenoid operated 
valve assembly 93. Valve assembly 93 functions to control the flow of 
hydraulic fluid to and from core cylinders 67. A return line 94 connects 
valve assembly 93 to reservoir 82. Lines 96 and 97 connect valve assembly 
92 to the rod ends and head ends of cylinders 67, respectively. Valve 
assembly 93 has solenoids 93A operable to control its operating positions. 
A control valve 98 interposed in line 96 has a variable or adjustable 
throat or passage 98A to restrict the flow of hydraulic fluid in line 96. 
Valve 98 has a movable plunger operable in response to a control hydraulic 
fluid under pressure. The control hydraulic fluid is carried by a line 99 
leading to a second control valve 125. Valve 98 is operable to regulate 
the flow of fluid out of the head or upper ends of cylinders 67. Valve 98 
also has a one-way check valve 98B allowing free flow of fluid to the rod 
ends of cylinders 67 and restricting the return flow of fluid from the rod 
ends of cylinders 67. The rate of return flow of hydraulic fluid through 
passage 98B controls the speed of the up operation of cylinders 67. 
Returning to FIG. 1, a coordinating control apparatus indicated generally 
at 101 is operable to control the operation of valves 90 and 98 in 
conjunction with the movement of cross head 18 relative to the movement of 
core 53. Apparatus 101 is operable to control the upward movement of core 
53 below packerhead 29 so that the core 53 follows in a close relationship 
the packerhead 29 as it moves up jacket 43 to form the concrete pipe. 
Apparatus 101 also controls the downward movement of packerhead 29 as 
packerhead 29 and core 53 move down through the pipe. The relative 
movements of core 53 and packerhead 29 are controlled to maintain a close 
clearance distance between core head 54 and the bottom of packerhead 29. 
Apparatus 101 has a first upright square rod 102 movably mounted in an 
upright tube or protective cylindrical casing 103. As shown in FIG. 2, a 
bracket 104 accommodates the upper end of rod 102. A bolt 106 connects 
tube 102 to bracket 104. A plurality of bolts 107 mount bracket 104 on the 
end of cross head 23. As shown in FIG. 3, tube 103 is connected to post 13 
with a plurality of brackets 108. Each bracket 108 is connected with a 
bolt 109 to post 13. 
Referring to FIG. 4, a second rod 111 is movably located in tube 103 below 
rod 102. A length adjustment means 112 comprising a threaded rod 113 is 
threaded into a threaded bore 114 in the lower end of rod 102. A nut 116 
locks rod 113 to rod 102. A second nut 117 secured to rod 113 guides rod 
113 in the tube 103 and accommodates a wrench for turning rod 113. Tube 
103 has a side opening 118 permitting the longitudinal adjustment of rod 
113. Rod 113 is adjusted by releasing lock nut 116 from the end of rod 
102. Nut 117 accommodates a wrench to turn rod 113 whereby the length of 
rod 113 relative to rod 102 is changed. The length of rod 113 determines 
the spacing between the bottom of packerhead 29 and the top 54 of core 53. 
A valve control mechanism indicated generally at 119, as shown in FIGS. 5 
and 6, is mounted on one end of platform 59. Valve control mechanism 119 
is operable to control valves 90 and 98 in response to the relative 
movement between cross head 18 and core 53. Valve control mechanism 119 
has a pair of control units 121 and 125 connected to lines 91 and 99, 
respectively, and a source of hydraulic fluid under pressure, as pump 81. 
Control units 121 and 125 are valves with movable plungers operable to 
restrict flow of fluid and check valve allowing free flow of fluid in one 
direction. Units 121 and 125 can be model DC-1200-S-10 valves manufactured 
by Parker Hannifin, Manatrol Division, Elyria, Ohio, U.S.A. 
First unit 121 has a movable plunger 122 and a roller 123 mounted on the 
end of plunger 122. 
Second unit 125 has a movable plunger 126 and a roller 127 rotatably 
mounted on the outer end of plunger 126. Units 121 and 125 are mounted on 
a bracket 129. A plurality of bolts 130 connect bracket 129 to the top of 
one end of platform 59. 
Second control rod 111 extends downwardly adjacent rollers 123 and 127. 
Second control rod 111, shown in FIG. 5, has a first recess 131 aligned 
with roller 123. Recess 131 is formed by a first upwardly inclined side 
wall 132 and a second downwardly inclined side wall 133. Side walls 132 
and 133 function as camming surfaces engageable with roller 123 to move 
the plunger 122 into unit 121 thereby restricting the flow of hydraulic 
fluid through the unit. 
Control rod 111 has a second recess 134 aligned with the roller 127. 
Control rod 111 has an upwardly and outwardly inclined side 136 forming 
the upper side of recess 134. Side 136 functions as a cam to move plunger 
126 into unit 125 to restrict the flow of hydraulic fluid through the 
unit. The back side of rod 111 rides on a pair of rollers 137 and 138 
which hold rod 111 in contact with rollers 123 and 127. As shown in FIG. 
6, a nut and bolt assembly 139 rotatably mounts roller 137 to bracket 128. 
A similar nut and bolt assembly (not shown) rotatably mounts roller 138 on 
bracket 128. 
Second control rod 111 is biased in an upward direction by a compression 
spring 141. Spring 141 surrounds the lower end 111A of rod 111 located 
below bracket 129. An upper end of spring 141 bears against a collar 142 
secured to rod 111 with a pin 143. A tube or sleeve 144 surrounds spring 
141. The lower end of sleeve 144 accommodates a threaded member 146. The 
upper end of threaded member 146 engages the lower end of spring 141. 
Threaded member 146 has a longitudinal bore 147 which allows rod end 111A 
to move down into the member 146 against the biasing force of spring 141. 
A locked nut 148 threaded on member 146 is turned against the bottom end 
of sleeve 144 to lock the position of member 146 on sleeve 144. The 
biasing force of spring 141 is adjusted by changing the position of member 
146 relative to sleeve 144. 
The operation or cycle of the machine 10 is as follows. The pipe form 43 
with pallet 44 and the steel reinforcing cage is initially mounted on the 
turntable 41 in the off bearing station. Turntable 41 is rotated with the 
power unit 42 to locate the form in the production station in vertical 
alignment with the packerhead 29 and core 53. Packerhead 29 is lowered to 
its lowest position with rollers 32 just above pallet 44. Hydraulic 
cylinders 36 and 37 are contracted to lower the cross head 18 which, in 
turn, positions packerhead 29 at the bottom of the mold 43. Valve 84 is 
operated to a position to supply fluid under pressure to the upper ends of 
the cylinders 36 and 37 and allow the fluid in the lower ends of the 
cylinders 36 and 37 to flow to the reservoir 82. 
Core 53 is now raised until its upper end 54 is in close proximity to the 
lower end of packerhead 29. This is accomplished by supplying hydraulic 
fluid under pressure to the lower or lift end of the core hydraulic 
cylinders 67. Valve 93 is actuated to a position to allow fluid under 
pressure to flow to the lower ends of cylinders 67 and allow the fluid to 
return from the upper ends of the cylinder 67 to the reservoir 82. 
Bell packer 68 is operated to engage the pallet 44. The conveyor 51 
functions to feed concrete into the mold 43 above packerhead 29. The 
concrete is placed into the bell of the pipe by the rotating packerhead 29 
and consolidated by the rotating and vibrating pallet 44. 
The rotating packerhead 29 packs the barrel of pipe 46 by centrifugally 
placing the concrete in the pipe wall and squeezing it with the rotating 
rollers 32. Core 53 follows the upward travel of packerhead 29. Vibrator 
26 operates constantly to thereby redensify the pipe concrete. This has 
the effect of relieving the stress on the steel cage. The core cylinders 
67 are supplied with hydraulic fluid under pressure by pump 81. The 
control valve 98 functions to restrict the flow of hydraulic fluid out of 
the upper end of the cylinders 67, thereby controlling the upward movement 
of the core. Control unit 125 will be actuated if the top of end 54 of 
core 53 moves too close to the bottom of packerhead 29. Roller 127 will 
move up on the inclined side 136 of rod 111. Actuation of plunger 126 
restricts the flow of hydraulic fluid into line 99 thereby actuating valve 
98 to restrict the flow of fluid from the upper end of lift cylinders 67. 
As soon as packerhead 29 moves away from the upper end 54 of the core 53, 
plunger 126 will return to its normal position, as the roller 127 moves 
down the inclined side 136. 
When core 53 has gone completely through the pipe, it is withdrawn by 
reversing the flow of hydraulic fluid to the core controlled cylinders 67. 
Control valve 84 is also actuated to move packerhead 29 down through pipe 
46 along with core 53. The distance between the lower end of packerhead 29 
and the top end 54 of core 53 is maintained by the operation of the 
coordinating control apparatus 101. If the packerhead 29 moves too close 
to the top end 54 of core 53, unit 121 will be actuated thereby 
restricting the flow of hydraulic fluid from the bottom ends of cylinders 
36 and 37. Roller 123 will ride up on the inclined surface 133 of rod 111 
thereby actuating the unit 121. Actuation of unit 121 causes valve 90 to 
restrict the flow of hydraulic fluid from the head ends of cylinders 36 
and 37 thereby allowing the downward movement of packerhead 29. 
As soon as the core 53 moves away from packerhead 29, roller 123 moves back 
into recess 131 whereby unit 121 signals the valve 91 to increase the flow 
of hydraulic fluid from the bottom ends of the cylinders 36 and 37. 
Packerhead 29 will follow the core 53 down through the completed pipe 46 
without touching or bearing on the top end 54 of the core 53. 
When core 53 is in its down or full retracted position, as shown in FIG. 1, 
packerhead 29 is raised out of the top of mold 43 by supplying hydraulic 
fluid under pressure to the cylinders 36 and 37. The top table 47 is 
lifted from pipe 46 and mold 43 when the bottom of the packerhead 29 is 
above table 47. Turntable 41 is then rotated by operation of the power 
unit 42. This places the completed pipe at the off bearing station. A new 
form with a steel cage and pallet is simultaneously moved into vertical 
alignment with the packerhead 29 and core 53 or a production station. The 
top table 47 is lowered onto the top of the mold 43. The cycle for forming 
the pipe in a new mold is then repeated. 
While there has been shown and described the preferred embodiment of the 
concrete pipe making machine and coordinated control apparatus for the 
packerhead and vibrating core, it is understood that changes in the 
machine and control apparatus can be made by those skilled in the art 
without departing from the invention. The invention is defined in the 
following claims.