SU1525002A1 - Table vibrator - Google Patents

Abstract

The invention relates to the manufacture of precast concrete and reinforced concrete products and reduces energy consumption by providing adjustment to the optimum mode of operation. This is achieved by the fact that the vibrating plate is provided with an additional valve 34 connected to the hydraulic pump 14, having a mode setting unit 37 and a throttle controller 35. The upper part 30 of the pusher 26 is made with a channel 33 connecting the variable volume chamber 32 with the additional valve 34, the throttle regulator 35 of which is connected to the drain tank 36. 1 Il.

Description

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The invention relates to the production of precast concrete and reinforced concrete.

The goal of the invention is to reduce energy consumption by providing a setting for optimal operation.

The drawing shows schematically vibroplatform, section.

The vibrating plate contains a working body 1, mounted on the base 2 by means of elastic supports 3, and a vibration exciter (not indicated), including a hydraulic cylinder 4 with a piston 5 and a rod 6 connected by a hinge 7. The rod 6 interacts with the working body 1. The piston 5 has channels 8 and 9, connecting chambers 10 and 11 of hydrostatic unloading of the piston 5 with the piston cavity 12 and with the rod cavity 13 of the hydraulic cylinder 4. The hydraulic pump 14 of the vibration exciter is connected to the cavities 12 and 13 through the distributor 15 and the pipelines 16 and 17. In the housing 18 distributor 15 mouth sleeve 19 with annular channels 20, 21, 22, vertically movable spool bushing 23 with annular recesses 24 and channels 25 and pusher 26 installed in axial bores 27 and 28 of sleeve 23 are added. The butt of the pusher 26 installed in the bore 28 is spring-loaded 29 relative to the housing 18, and the end face of the pusher 26 mounted in the bore 27 is spherical and interacts with the piston 5. The pusher 26 is made of two parts 30 and 31, between which the variable volume damper chamber 32 is located. The damper chamber 32 is connected to the discharge pipe 16 via the additional valve and conduit 33 through the additional distributor 35 to the drain tank 36. The additional distributor 34 is controlled from the operating mode setting 37. The hydraulic pump 14 is connected to the drain tank 36 through the safety valve 38.

The vibrating platform works as follows.

In the initial position, the spring 29 displaces the stop 31 upwards, which ensures the minimum volume of the damping chamber 32 and the minimum gap between the stops of the pusher 26 and the vertically-visible spool sleeve 23. The working body 1 through the rod 6, the piston

0 5 Q 5 about 5

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5 and the top 30 of the pusher 26 pulls the spool sleeve 23 BHHS,

When the hydraulic pump 14 is turned on, the liquid through the pipeline 16 through the channel 21 and the serrated annular grooves 24 of the spool bushing 23 enters the axial bore 27 and the hydraulic cylinder 4 piston cavity 12 moves the piston 5 upwards and slides the sliding bushing 23 to the neutral . Due to the inertia of the working body 1, the spool bushing will pass the leitral, the channel 21 of the sleeve 19 is connected through the channels 25 to the bore cavity 28. As a result, the spool sleeve 23 will be transferred to the upper position until it stops at the lower end of the plunger 30. The working fluid will enter the piston cavity through the pipe 17 13 hydraulic cylinders, and the piston 5 will begin to move down. The working fluid from the piston cavity 12 through the axial bore 27 and the radial holes of the spool sleeve 23 is pushed into the annular channel 20 and further along the drain pipe into the drain tank 36. The spool sleeve 23 is displaced to the neutral and, due to the inertia of the working body 1, passes it. The working fluid from the hydraulic pump 14 enters the bore 27, the spool bushing 23 is transferred to the lower position all the way to the end of the pusher 31. Through the boring 27, the working fluid enters the piston cavity 12 and the piston 5 begins to move upwards. The cycle is repeated.

When power is applied to the mode selector 37, which is a programmable time relay, the timing starts. After the time t expires, the operation mode setting unit 37 supplies power to the coil of the additional distributor 34, the spool is transferred, and the working fluid from the hydraulic pump 14 is fed through the channel 4 to the pipe 33 into the damper chamber 32 of the pusher 26. As a result, the components 30 and 31 are moved apart, and the gap becomes maximized. The operating element oscillates with a low frequency and a large amplitude. After time t, the operation mode setting unit 37 turns off the power from the additional distributor 34 and its spool is transferred to the left position. The damper chamber 32 is connected to the drain tank 36 via the throttle regulator 35. The working fluid is gradually expelled from the damper chamber 32, the gap between the current collector and the spool bushing 23 decreases, resulting in a smooth increase in qacTota of oscillation of the operating member 1 and a decrease in the oscillation amplitude. By adjusting the operation mode setting 37 with the duration ti and t of supplying power to the additional distributor FOR, as well as adjusting the throttle controller 35, one can achieve the best mode for changing the vibration parameters during the product molding cycle.

F

formula of the invention. A vibrating platform containing a working body supported on the base by means of elastic supports connected by means of a rod with a piston placed in the hydraulic cylinder of the oscillation activator, the bottom of which contacts the spherical upper

part of the pusher, forming with its lower, having an emphasis, spring-loaded part of the chamber of variable volume, the pusher is located along the central axis of the vertically movable spool bushing of the distributor and hydraulic pump connected through the distributor and the safety valve, respectively, to the cylinder cavity of the drain tank, which differs so that, in order to reduce energy consumption by providing adjustment to the optimal mode of operation, it is equipped with an integrated hydraulic pump nym distributor having dial mode and a throttle controller, and the upper part of the pusher is formed with a channel binding variable volume chamber with an additional control valve, the throttle controller is connected to a drain tank.

Claims (1)

Formula of the invention A vibrating platform containing a working body supported by elastic supports, pivotally connected by means of a rod to a piston located in the hydraulic cylinder of the oscillator exciter housing, the bottom of which is in contact with the spherical upper part of the pusher forming a variable-volume chamber with a spring-loaded part and a spring-loaded part 5, the pusher is located along the central axis of the vertically movable spool sleeve of the distributor installed in the sleeve of the housing and a hydraulic pump connected through inlet IQ flow and safety valve, respectively, with the cavities of the hydraulic cylinder by a drain tank, characterized in that, in order to reduce energy consumption by ensuring tuning to the optimal operating mode, it is equipped with an additional distributor connected to the hydraulic pump having an operating mode adjuster and a throttle regulator, and the upper part The pusher20 is made with a channel connecting a variable volume chamber with an additional distributor, the throttle controller of which is connected to the drain tank.