RU114068U1 - UNIVERSAL PRESSING DEVICE - Google Patents

Abstract

The utility model relates to construction equipment, namely to pressing devices, designed for shockless and noiseless immersion of piles, piles, pipes, tongues of any existing standard sizes and other pile elements into the soil and can be used in civil, industrial, energy and road construction , is aimed at increasing the asymmetry coefficient of the total directed inertial force, increasing labor productivity, reducing power consumption, reducing material consumption and with noise reduction in operation, this is achieved due to the fact that the universal pressing device made of single-pulse or double-pulse contains a traverse beam - 1, guides - 2, a removable gripper - 3, an inertial polyharmonic self-balancing vibrator - 4, including a housing - 5, bearing supports - 6, 7, 8, 9, 10, 11, 12, 13, toothed belts 14, 15, the number of which may be different from two, tension rollers 16, toothed pulleys 17, 18, 19, 20, 21, 22, 23, 24 and pairwise equivalent unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32, combined in separate groups ppy associated with rotary drive 33 (hereinafter JHA). The axes of pairwise equivalent unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32 are located mainly in different vertical planes. In the housing 5, said gear pulleys 17, 18, 19, 20, 21, 22, 23, 24 and pairwise equivalent unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32 with certain design parameters and certain design static moments of unbalance: initial - 17 and 25 and additional - 18 and 26, 19 and 27, 20 and 28, 21 and 29, 22 and 30, 23 and 31, 24 and 32 are placed in two eight-stage equivalent series. At the same time, the named unbalanced pairs are successively kinematically in a multiplicative manner, by means of engagement of their respective pairs of gear pulleys: - 17, 18, 19, 20, 21, 22, 23, 24, rigidly interconnected by gear belts 14, 15 and tension rollers 16 mounted in the respective bearing bearings 6, 7, 8, 9, 10, 11, 12, 13 of the bearing walls of the housing - 5 with the ability to rotate in pairs synchronously and in-phase in opposite directions.

The number of additional pairwise equivalent unbalanced shafts 26, 27, 28, 29, 30, 31, 32 attached to the initial pair is assumed to be seven. The order of the rotation frequency of each additional pair relative to the initial pair is selected integer from the range 1-16. The phase shift angles of each additional pair relative to the initial are taken equal to zero. The unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32 of the predominantly final upper pair are kinematically connected with the LDPE made in the form of a block 33, consisting of two equivalent mechanical gears and two equivalent electric motors 36, servomotors, hydraulic motors can also be used and other rotary motion drives operating synchronously with the possibility of smoothly controlling the rotation speed and controlled by the remote control 34. The number of electric motors 36 may be different from two. Electric motors 36 can be placed on the top cover 37 of the housing 5 or the side walls 38 of the housing 5.

Presented in figure 2, the asymmetry of the total directional inertial force of a single-pulse inertial polyharmonic self-balancing vibrator made according to the eight-step scheme of the proposed universal pressing device, by definition, is equal to

Kн = Fи _∑наиб / Fи _∑наим = 8, where:

K _n - asymmetry coefficient of the total directed inertial force;

Fi and _∑aib - the largest value of the total directed inertial force; F and _∑name - the smallest value of the total directed inertial force.

Presented in figure 3, the diagram of the change in the total directional inertial force of a two-pulse inertial polyharmonic self-balancing vibrator made according to the nine-stage scheme of the proposed universal pressing device is, by definition, equal to

Kн = Fи _∑наиб / Fи _∑наим = 8, where:

K _n - asymmetry coefficient of the total directed inertial force;

Fi and _∑aib - the largest value of the total directed inertial force;

F and _∑name - the smallest value of the total directed inertial force. 1 s.p. f-ly.

Description

The utility model relates to construction equipment, namely to pressing devices, and is aimed at increasing the asymmetry coefficient of the total directed inertial force, increasing labor productivity, reducing power consumption, reducing material consumption and reducing noise in work, is intended for shockless and silent immersion in piles of soil, pile-shells, pipes, dowels of any existing standard sizes and other pile elements and can be used in civil, industrial, energy and other road construction.

Analysis of various immersion devices shows that the specific gravity of directional inertial self-balancing gear vibrators in the overall arrangement of shock, vibration-absorbing and combined devices accounts for the largest share, carries the greatest functional load, and this provides the largest component of the effect of using this equipment.

Vibration-shock, vibration-absorbing and combined devices of various designs are known, containing inertial inertial self-balancing gears of different sizes, including a housing with one, two, three or even four pairs of equivalent hard-wired gear wheels and shafts, which create rotation in opposite directions directed inertial forces, periodically and symmetrically changing in magnitude, designed to excite oscillations and widely at enyaemye worldwide in a variety of vibrating devices and installations.

Vibro-type vibro-loaders of domestic production are also widely known, intended (for example, the VP-2 and VP-3 models with the possibility of working in the dual-frequency mode) for immersing heavy reinforced concrete piles and piles-shells, including gear inertial self-balancing biharmonic vibrators containing integer groups in pairs equivalent, synchronously rotating in opposite directions unbalanced gears and shafts, combined in a single housing, and creating a total directional inertial force that varies about the value periodically, both symmetrically and not symmetrically, designed to disturb the vibrations in O.A.Savinov, A.Ya. Luskin // Vibration method of pile driving and its application in construction, State Publishing House of Literature on Construction, Architecture and Building Materials : L., M, 1960, pp. 63-66.

Disadvantages: the technological capabilities of this mechanism are limited due to the insufficient value of the asymmetry coefficient of the total directional inertial force, which is the ratio of the highest value of the total directed inertial force to the smallest (K _n = F and _{∑ inaib} / F and _{∑ inay} = 2), for a self-balancing toothed biharmonic vibrator equal to two. It is impossible to achieve large values of the asymmetry coefficient of the total directional inertial force with the help of a biharmonic vibrator. A serious drawback is the transfer of destructive vibrations from the vibrator to the base machine. The design of the analogue is intended to work only in water-saturated soils and is not applicable in dry heavy soils. Also, the analogue under consideration has a high power consumption. These shortcomings cannot provide high labor productivity.

The known prototype universal pressing device in the description of the invention to the patent of the Russian Federation No. 2388868, IPC E02D 7/00 from 02.24.2009, publ. 05/10/2010, which contains a cargo beam, guides, a replaceable pile headgear and a gear inertial self-balancing vibrator, including a housing, bearing bearings, pairwise equivalent rigidly interconnected unbalanced gears and shafts, united in separate groups associated with the drive. The inertial self-balancing toothed vibrator is polyharmonic, pairwise equivalent unbalanced gears and shafts are connected in series in multiplicative order to each other in two equivalent vertical rows. The unbalanced shafts of the final upper pair are kinematically connected with the rotary drive made in the form of a block of two equivalent mechanical gears and two equivalent engines, the static moments of unbalance of each additional pair are selected from the condition of the necessary asymmetry of the directed total directional inertial force from the range of 3 ÷ 7, while dead weight of the universal pressing device is selected taking into account the magnitude of the above asymmetry of the total inertial force and the smallest value riticheskogo breakdown resistance of the immersion member. Asynchronous motors or servomotors can be used in a rotary motion drive.

Disadvantages: insufficient value of the asymmetry coefficient of the total directional inertial force, which is the ratio of the highest value of the total directed inertial force to the smallest (K _n = F and _∑naib / F and _∑найм = 7), for a toothed inertial polyharmonic self-balancing vibrator made according to a seven-step scheme equal to seven, insufficiently high labor productivity, high power consumption and material consumption, high noise level during operation. Used cylindrical gears by themselves create additional noise in operation, require lubrication and additional sealing of the structure.

Effect: increase the asymmetry coefficient of the total directed inertial force, increase labor productivity, reduce power consumption, reduce material consumption and reduce noise in the work.

The technical result is achieved due to the fact that a universal pressing device containing a load beam, guides, a gear inertial self-balancing vibrator, including a housing, bearing bearings, pairwise equivalent, rigidly interconnected unbalanced shafts, united into separate groups associated with a rotary drive characterized in that the universal pressing device made single-pulse or double-pulse, contains a removable gripper, inertial polyharm self-balancing vibrator including gear pulleys, belts, tension rollers, pairwise equivalent unbalanced shafts, while gear pulleys, pairwise equivalent unbalanced shafts, the axes of which are located mainly in different vertical planes, are connected in series in a multiplicative manner by engagement of gear pulleys , toothed belts, the number of which can be different from two, in two equal rows mounted in bearing bearings of the bearing walls of the housing, and toothed pulleys the initial pair of ordinary joints are kinematically also connected with each other, while the number of additional pairwise equivalent unbalanced shafts connected to the initial pair is selected from the range of 2 ÷ 9, the order of the speed of each of them relative to the initial pair is selected integer from the range of 1 ÷ 18, unbalanced shafts of a predominantly final upper pair are kinematically connected to a rotary drive connected to the remote control and made in the form of a block of two equivalent mechanical gears and two p of unique engines, the number of which can be different from two, located on the upper cover of the case or on the side walls of the case working synchronously with the possibility of smooth adjustment of the rotation frequency, the static moments of the unbalanced shafts of each additional pair are selected from the condition of the required asymmetry coefficient of the total directional inertial force from range 3 ÷ 10, moreover, in the rotary drive as equivalent motors, electric motors or hydraulic motors, or motors operating synchronously with the possibility of smoothly controlling the speed of rotation and controlled by an external remote control, and the generated total directional inertial forces are selected from the range: 0.1-0.5, 0.5-25, 25-75, 75-110, 110-250 , 250-500, 500-800, 800-1200, 1200-1500, 1500-3000 tons.

An increase in the asymmetry coefficient of the total directed inertial force, an increase in labor productivity, and a decrease in power consumption is achieved due to the fact that the introduced gear pulleys, gear belts, and tension rollers make it possible to increase the number of additional pairwise-equivalent unbalanced shafts attached to the initial pair, to perform a universal pressing device of eight and more stepwise, which allows to increase the asymmetry coefficient of the total directional inertial force and the choice of static moments of unbalanced shafts and speed parameters of each additional pair of unbalanced shafts with respect to the initial pair, allowing to obtain two pulses per revolution of the initial pair of unbalanced shafts (Fig.3) allows to increase labor productivity by 2-2.5 times.

The reduction in power consumption is achieved due to the fact that the introduced gear pulleys, gear belts and tension rollers allow you to increase the number of additional pairwise-equivalent unbalanced shafts attached to the initial pair and to perform a universal pressing device of eight or more steps, increasing the gear ratio from the rotary drive to initial pair of unbalanced shafts.

The reduction in material consumption is achieved due to the fact that the introduced gear pulleys, gear belts and tension rollers allow to reduce the interaxal distances between pairwise-equivalent unbalanced shafts, the axes of which are located mainly in different vertical planes, and even an increased number of additional pairwise-equivalent unbalanced shafts attached to the initial pair, allows you to get the design of a universal pressing device more compact and light.

Noise reduction in work is achieved due to the fact that gear pulleys, gear belts and tension rollers are introduced.

The analysis of the prior art showed that the claimed combination of essential features set forth in the formula of the utility model is unknown. It is established that the claimed technical solution does not follow explicitly from the prior art. This allows us to conclude that it meets the condition of patentability "novelty" and the condition of industrial applicability. Using the inventive device ensures the achievement of a technical result: an increase in the asymmetry coefficient of the total directed inertial force, an increase in labor productivity, a decrease in power consumption, a decrease in material consumption, and a decrease in noise in operation.

The essence of the utility model is illustrated by drawings, where

figure 1 shows a diagram of a universal pressing device;

figure 2 presents a diagram of the change in the total directional inertial force of a single-pulse inertial polyharmonic self-balancing vibrator made according to an eight-stage device diagram;

figure 3 presents a diagram of the change in the total directional inertial force of a two-pulse inertial polyharmonic self-balancing vibrator made according to a nine-stage device circuit.

A universal pressing device made of single-pulse or double-pulse contains a traverse beam - 1, guides - 2, a removable gripper - 3, an inertial polyharmonic self-balancing vibrator - 4, including a housing - 5, bearing bearings - 6, 7, 8, 9, 10, 11, 12, 13, toothed belts 14, 15, the number of which may be different from two, idler rollers 16, toothed pulleys 17, 18, 19, 20, 21, 22, 23, 24 and pairwise equivalent unbalanced shafts 25, 26 , 27, 28, 29, 30, 31, 32, combined into separate groups associated with the rotary drive 33 (yes its LDPE).

The axes of pairwise equivalent unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32 are located mainly in different vertical planes. In the housing 5, said gear pulleys 17, 18, 19, 20, 21, 22, 23, 24 and pairwise equivalent unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32 with certain design parameters and certain design static moments of unbalance: initial - 17 and 25 and additional - 18 and 26, 19 and 27, 20 and 28, 21 and 29, 22 and 30, 23 and 31, 24 and 32 are placed in two eight-stage equivalent series. At the same time, the named unbalanced pairs are successively kinematically in a multiplicative manner, by means of engagement of their respective pairs of gear pulleys: - 17, 18, 19, 20, 21, 22, 23, 24, rigidly interconnected by gear belts 14, 15 and tension rollers 16 mounted in the respective bearing bearings 6, 7, 8, 9, 10, 11, 12, 13 of the bearing walls of the housing - 5 with the ability to rotate in pairs synchronously and in-phase in opposite directions.

The number of additional pairwise equivalent unbalanced shafts 26, 27, 28, 29, 30, 31, 32 attached to the initial pair is assumed to be seven. The order of the rotation frequency of each additional pair relative to the initial pair is selected integer from the range 1-16.

The phase shift angles of each additional pair relative to the initial are taken equal to zero. The unbalanced shafts 25, 26, 27, 28, 29, 30, 31, 32 of the predominantly final upper pair are kinematically connected with the LDPE made in the form of a block 33, consisting of two equivalent mechanical gears and two equivalent electric motors 36, servomotors or hydraulic motors can also be used , or other rotary motion drives operating synchronously with the possibility of smoothly controlling the rotation speed and controlled by the remote control 34. The number of electric motors 36 may be different from two. Electric motors 36 can be placed on the top cover 37 of the housing 5 or the side walls 38 of the housing 5.

Presented in figure 2, the asymmetry of the total directional inertial force of a single-pulse inertial polyharmonic self-balancing vibrator made according to the eight-step scheme of the proposed universal pressing device, by definition, is equal to

Kн = F _{и∑наиб} / F _{и∑наим} = 8, where:

Kн is the asymmetry coefficient of the total directed inertial force;

Fi and _∑aib - the largest value of the total directed inertial force;

F and _∑name - the smallest value of the total directed inertial force.

Presented in figure 3, the diagram of the change in the total directional inertial force of a two-pulse inertial polyharmonic self-balancing vibrator made according to the nine-stage scheme of the proposed universal pressing device is, by definition, equal to

Kн = Fи _∑наиб / Fи _∑наим = 8, where:

Kн is the asymmetry coefficient of the total directed inertial force;

Fi and _∑aib - the largest value of the total directed inertial force;

F and _∑name - the smallest value of the total directed inertial force.

The device operates as follows.

A universal pressing device, mounted by means of a cargo beam 1 on the hook holder of the lifting crane and installed in the guides of its pile stand by means of guides 2 (it is allowed in the absence of a pile stand and a simple suspension on the hook clip), is brought by the crane driver to a special rack with it laid on it under a slope 6-7 degrees to the horizon with pile elements and a removable gripper 3 is put on the pile element 35. The assistant to the driver using the remote control 34 with a removable gripper 3, clamps the pile element 35. On the command of the assistant, the crane operator puts the pile element 35 in a vertical position, brings it to the dive point and puts the load winch in the release mode. The assistant to the driver through the remote control 34 includes the LDPE 33, the torque of the shafts of the electric motors 36 located on the top cover 37 or the side walls 38 of the housing 5, is transmitted via mechanical gears to the gear pulleys 24 connected by a fixed connection to their unbalanced shafts 32 and located in their bearing bearings 13, then the torque is transmitted to the gear pulleys 23, 22, 21, 20, 19, 18, 17 by means of gear belts 14 and 15, tensioned by means of their tension rollers 16, connected by a fixed connection to their deb with the ensemble shafts 31, 30, 29, 28, 27, 26, 25 located in their bearing bearings 12, 11, 10, 9, 8, 7, 6 located in the bearing walls of the housing 5. Unbalanced shafts synchronously and in-phase rotating in opposite directions 25, 26, 27, 28, 29, 30, 31, 32 create the total directional inertial force of the inertial polyharmonic self-balancing vibrator 4, the change diagram of which is illustrated by figures 2 and 3. This force is transmitted through the gripping device 3 to the pile element 35 and its smooth dive to a given depth. Then, the assistant to the driver through the remote control 34 releases the pile element 35 from the clamp in the gripping device 3. The crane driver, at the command of the assistant, lifts the device and ... then the cycle repeats.

The technical and economic effect of using the proposed technical solution is expressed in increasing the asymmetry coefficient of the total directed inertial force, increasing labor productivity by 2-2.5 times, reducing power consumption, reducing material consumption and reducing noise in the work and on its basis the creation of new high-performance energy-saving technologies and devices primarily for the construction industry: shock-free and silent universal pressing devices, vibration-absorbing and vibrating shock devices, vibration-penetrating injection devices for the manufacture of wells without excavation and high-quality rammed piles with increased bearing capacity, piercing devices for water wells, and many others. other

The inventive utility model is experimentally mastered in the city of Voronezh at the enterprise LLC Vibronovatsiya Engineering Center since 2011.

The list of positions.

1 - cargo beam;

2 - guides;

3 - removable gripper;

4 - inertial polyharmonic self-balancing vibrator;

5 - case;

6, 7, 8, 9, 10, 11, 12, 13 - bearing bearings;

14, 15 - timing belts;

16 - tension rollers;

17, 18, 19, 20, 21, 22, 23, 24 - gear pulleys;

25, 26, 27, 28, 29, 30, 31, 32 - unbalanced shafts;

33 - drive rotational motion;

34 - remote control;

35 - pile element;

36 - electric motor;

37 - top cover;

38 - side wall.

Claims (1)

A universal pressing device containing a cargo beam, guides, a toothed inertial self-balancing vibrator including a housing, bearing bearings, pairwise equivalent, rigidly interconnected unbalanced shafts, united into separate groups associated with a rotary drive, characterized in that the universal pressing device made single-pulse or double-pulse, contains a removable gripping device, an inertial polyharmonic self-balancing vibrator, including a gear pulleys, belts, tension rollers, pairwise equivalent unbalanced shafts, while gear pulleys, pairwise equivalent unbalanced shafts, the axes of which are located mainly in different vertical planes, are connected in a multiplicative manner to each other by engaging toothed pulleys, toothed belts, the number of which can be different from two, in two equivalent rows mounted in the bearing bearings of the bearing walls of the housing, and the gear pulleys of the initial pair of ordinary connections kinematically so e are related to each other, while the number of additional pairwise equivalent unbalanced shafts attached to the initial pair is selected from the range of 2 ÷ 9, the order of the rotation speed of each of them relative to the initial pair is selected integer from the range of 1 ÷ 18, unbalanced shafts of the final upper pair are kinematically connected to a rotary motion drive associated with the remote control and made in the form of a block of two equivalent mechanical gears and two equivalent engines, the number of which can be different from the two located on the top cover of the case or on the side walls of the case working synchronously with the possibility of smooth control of the rotation frequency, the static moments of the unbalanced shafts of each additional pair are selected from the condition of the necessary asymmetry coefficient of the total directional inertial force from the range of 3 ÷ 10, while rotational motion drive as equivalent motors can be applied electric motors, or hydraulic motors, or servomotors operating synchronously with the possibility of stepless speed control and controlled by the remote control, and the generated total directional inertial forces are selected from the range: 0.1-0.5, 0.5-25, 25-75, 75-110, 110-250, 250-500, 500 -800, 800-1200, 1200-1500, 1500-3000 t.