RU154516U1 - Inertia drum for winding hoses - Google Patents

Abstract

1. An inertial drum for winding hoses, comprising a U-shaped housing, between the side walls of which a horizontal drum is mounted in the bearings, in which one end of the winding hose is fixed, connected to a fan or ventilation system, a gas inlet nozzle is attached to the other end of the hose for connecting and fixing on the exhaust pipe of the car and the drive for winding the hose onto the drum with fixing the position of the hose in the desired position, characterized in that the drive is made in the form of a balancing balancer, with of a cam mounted on the outer side of the cam body, the focus of which is rigidly fixed on the drum axis, and a vertically located air spring whose stem is directed away from the cam, a rotating pulley is fixed at the end of the rod, and the pulley and cam, on the outer side of which there is a flange, are bent the cable passing through the guide roller and wound around the cam when the hose is unwound, for which one end of the cable is mounted on the cam and the other on the outside of the housing after the cable passes through the pulley, with the poppy the maximum and minimum sizes of the cam shoulders are determined by the formulas: L≥ (P + 3P) R / k / 2; L≥ (P + 5P) R / 2k / 2, where P is the weight of the gas inlet nozzle, kg; P is the weight of one meter of the hose, kg; k is the stiffness (elasticity) of the air spring, N / m; R is the radius of the drum, m; L- maximum cam shoulder, m; L- minimum cam shoulder, m. 2. The inertial drum according to claim 1, characterized in that the cam is in the form of an ellipse, the focus of which is located on the axis of symmetry in its center. The inertial drum according to claim 1, characterized in that the cam has the shape of an ovoid, the focus of which is located on the axis of symmetry in the center

Description

The utility model relates to the field of automotive industry, in particular to exhaust systems of automobiles for various bench tests of a car conducted in a room, and can be used for exhaust gas removal devices to reduce toxicity in rooms where cars with an internal combustion engine are tested, as well as removal of other gaseous hazards from non-stationary sources.

Various devices are known for remote exhaust gas removal outside the building, for example, according to RF patents Nos. 20399, 51780, 2528767, US patents Nos. 5927759, 5096230. These devices contain the capture of gases from the exhaust pipe of the internal combustion engine and the direction of these gases out of the building. For this, devices containing a flexible hose with a tip (gas nozzle) are used to connect the hose to the exhaust pipe of the vehicle. The other end of the hose is connected to a ventilation hole, for example, in the roof of a building. However, these devices do not include drums for winding connected hoses.

Known lifting mechanisms, for example, hoists, balancers designed to pull on the drum of the cable in the absence of exposure to any lowering force. Such balancers are used when it is necessary to facilitate the work of the operator with heavy equipment or tools.

There are various sports dynamometers (force meters), for example, "Silo device for trainers" according to the patent of the Russian Federation No. 7610, containing a housing, brake drum, a transmission mechanism for rotation of the brake drum, an exhaust cord, which rotates the shaft of the brake drum and a spring mechanism that returns the winding drum with lanyard to its original position.

Known mechanisms for winding wire onto the drum of a vacuum cleaner, for example, “Cable drum” according to the patent of the Russian Federation No. 2264158 and “Device for storing the cable” according to the patent of the Russian Federation No. 2268636. This device contains rollers placed on the side of the entrance to the storage cavity on a pendulum housing mounted to swing around an axis, the device comprising at least one first and at least one second roller, between which the cable passes and is inserted into the storage cavity. In this case, at least two second rollers are located on one side of the cable and are mounted on the respective axes in the pendulum case, and due to the persistent interaction of the cable with the second roller or with the second roller, the pendulum movement is carried out.

A device for the reverse retraction of the seat belt strap according to the patent of the Russian Federation No. 2177813, containing an inertial coil, in the U-shaped case of which is mounted rotatably mounted shaft with a spool for winding or reeling the seat belt strap, a coil spring for rotating the shaft in the direction of winding the strap, clutch compulsory reverse rotation of the shaft, comprising a drum fixed to the shaft and a separator fixed to the housing with a loop-shaped flexible traction in the form of a rope laid around it with a gap around the drum, one section of which is brought out and threaded through the brake cams of the separator, and the opposite section is led out through the guide channel into the pyrotechnic device, as well as an inertial-touch ratchet mechanism for blocking the shaft during accelerated pulling of the belt strap

All these devices are combined in that they contain a winding drum, a drive rotating this drum, made, for example, in the form of a spring, with an upward force applied to create a substantially constant rotational force to the drive axis, as well as a control mechanism ( balancing balancer or brake link), which allows you to return (wind) the wire (hose, tape, flexible pipe) back to the drum without acceleration at a small constant speed after the removal (termination) of the downward force.

As a prototype, “SER-P / SP exhaust coil” manufactured by SovPlim CJSC (website www.sovplym.ru) was selected. The prototype contains a housing in which a horizontally hollow drum is mounted on bearings, a spring mechanism that ensures the hose is wound on the drum, a stopper that provides the required length of the hanging hose in the inoperative position, a stopper, a fixing hose in the desired position, made in the form of a ratchet mechanism, and on At the end of the hose there is a fastening mechanism (flange) of the gas intake nozzle for fixing it on the exhaust pipe of the car. The drum is attached to the ceiling or to the wall, occupying a minimum of space and without interfering with the technological process. When inoperative, the exhaust hose is wound around the drum. When connected to the exhaust pipe, the hose is unwound under the applied force to the desired length; when disconnected, the hose is wound on the drum under the action of a return spring.

In the design of the above analogues, as well as the prototype, a flat coil spring is used as a drive, and a ratchet mechanism is used as a stop. However, when using them, the hose at maximum unwinding will experience a sufficiently large tensile load, many times greater than at the initial moment of unwinding (spring property). For this reason, for such coils, it is necessary to use strong, and therefore more expensive and heavier hoses, this in turn increases the required minimum moment for winding, which makes these devices quite dangerous in the event that the hose accidentally falls out of the operator’s hands or breaks off the exhaust pipe and starts with acceleration along an unpredictable trajectory to wind around the drum. In addition, the rapidly increasing unwinding torque limits the length of the hose used.

The problem the utility model aims to solve is to create a safe inertial drum for winding hoses, the use of which will provide such a technical result as obtaining the minimum optimal winding moment for various flexible air ducts (hoses).

This technical result is obtained in the technical solution of an inertial hose reel containing a U-shaped body, in the side walls of which a horizontal drum is mounted on bearings, in which one end of the reeled hose is connected, connected to the fan or to the ventilation system, at the other end the gas intake nozzle is fixed to the hose for connecting and fixing to the exhaust pipe of the car and the drive for winding the hose onto the drum with fixing the position of the hose nga in the desired position. In this case, the drive is made in the form of a balancing balancer, consisting of a cam mounted on the outside of the cam body, the focus of which is rigidly fixed on the drum axis, and a spring located vertically, the stem of which is directed away from the cam, a rotating pulley is fixed at the end of the rod, with the pulley and cam , on the outer side of which there is a flange, they are bent around by a cable passing through the guide roller and wound around the cam when the hose is unwound, for which one end of the cable is fixed to the cam, and the other to the outside the case of the housing after the cable passes through the pulley, while the maximum and minimum sizes of the cam shoulders are determined by the formulas found empirically for hoses of different weights:

L _max ≥ (P ₁ + 3P2) R / k / 2; Lmin≤ (P1 + 5P2) R / 2k / 2, where

P ₁ - the weight of the gas receiving nozzle in kg;

P ₂ - the weight of one meter of hose in kg;

k is the stiffness (elasticity) of the air spring in N / m;

R is the radius of the drum in m;

L _max - maximum cam shoulder in m;

L _min - minimum cam shoulder in m.

In the particular case, when the stroke of the rod of one pneumatic spring and, accordingly, the length of the envelope of the cable for the required number of revolutions of the drum is not enough, then the said balancer can consist of several pneumatic springs having a rotating pulley at the end of the rod, and installed in parallel and in pairs opposite (counter) to each other, whose pulleys are sequentially bent around with a cable, while the required number of air springs is calculated by the formula

N = nL / 2L ₁ , where

L is the length of the forming surface of the cam in mm;

L ₁ - maximum stroke of the pneumatic spring in mm;

2L ₁ - the length of the cable wound around the cam at maximum compression of the air spring in mm;

n is the number of revolutions of the drum (for winding the required length of the hose);

N - the required number of air springs in pcs.

Three other particular cases provide for the three most optimal cam shapes: ellipse, ovoid, equilateral triangle, which can be used for various weight and size characteristics of the inertial drum.

The essence of the utility model is illustrated by two figures (Figs. 1 and 2), which depict an inertial drum with a drive having one pneumatic spring (Fig. 1) and four pneumatic springs (Fig. 2).

The inventive inertial drum contains a hollow drum 1, a U-shaped housing 2, a bearing assembly 3, an air spring (s) 4, a pulley (block) 5 through which a cable passes, a holder 6, cams 7, 8 or 9, a guide roller 10, a cable 11, gas inlet nozzle 12, duct (hose) 13 and restrictor 14.

The hollow drum 1 on the axis is fixed in bearings 3 between two brackets (walls) of the U-shaped housing 2 and has the ability to freely rotate in one and the other direction. A cam 7, 8 or 9 is fixed at one end of the axis of the drum, with the end of the cable 11 fixed on it, the second end of which is fixed with the holder 6 on the bracket of the housing 2. When the hose is unwound from the drum 1, the cable is wound on the cam, and passing through pulleys mounted on the rods of air springs compresses (cockes) the air spring (s) 4.

This (pneumatic) inertial mechanism differs from the spring one with a ratchet lock in that the unwinding force remains almost unchanged (the properties of pneumatic springs in compressed air), and is selected by the geometry and dimensions of the cam depending on the elasticity (stiffness) of the pneumatic spring, which is set by the manufacturer, with taking into account the weight of the reeled hose and gas intake nozzle. Due to this selection, it is possible to create a minimally optimal moment of winding onto the drum of flexible air ducts (hoses) of various weights (depending on diameter and material), so that when unwinding the hose experiences a constant minimum burst load. In addition, the use of the claimed device will allow the use of lighter and cheaper hoses, as opposed to devices with spring mechanisms, for which it is necessary to use heavy expensive hoses with a large margin of tensile strength.

Typically, such winding mechanisms are installed in enclosed spaces at a height of 3-5 m from the axis of the drum 1 to the floor with the hanging end of the hose 13 (about 1 m) with a gas intake nozzle 12 and a winding limiter 14 for ease of maintenance so that the hose does not interfere with working personnel and passing people to motor transport. At the end of the unwinding hose 13 for fixing it on the exhaust pipe of the internal combustion engine (or other source of harmful emissions), a metal gas intake nozzle 12 with a fixing mechanism is fixed. The weight of the nozzle, as a rule, exceeds the weight of 1 m of the hose 2–3 times for heavy hoses and 8–10 times for light hoses. So the optimal force required for winding a hose with a nozzle to a 5-meter height must overcome the moment created by the weight of 3 meters of a hose with a limiter and nozzle weight. The missing 2 m is compensated by raising the nozzle with the hose to the height of a raised hand.

In order to optimize the drive effort for various weight and size characteristics of the drum with a hose for its fixing, unwound to the desired length, we experimentally selected cams of conventionally three geometric shapes: egg-shaped (ovoid) 7, which creates one minimum and one maximum moment (for all types of hoses), ellipse 9, creating two minimum and two maximum moments per revolution (for all types of hoses) and triangular 8, creating three minimum and three maximum moments per revolution (for I'm heavy hoses). If, when using the claimed device, while unwinding a hose with a nozzle, it accidentally falls out of the operator’s hands or falls off the exhaust pipe, then after winding it by 1/2 turn of the drum maximum (depending on the shape of the cam), the hose will remain on the floor, but will not speeding up onto the drum along an unpredictable trajectory with the possibility of damaging nearby cars and / or injuring personnel. If you lift the hose from the floor by the nozzle, the hose will begin to wind on the drum. Holding the nozzle in your hands and walking at the speed of winding towards the drum, you can wind the entire hose with the nozzle to the limiter. If the weight of the hose (when unwinding is close to maximum, mainly when using heavy hoses) exceeds the minimum winding moment created by the drive cam in a certain position, you should unwind the hose slightly and thereby move the cam to the position corresponding to the maximum winding moment, which will cause the drum turn and wind the hose due to the inertia of its rotation.

Claims (5)

1. An inertial drum for winding hoses, comprising a U-shaped housing, between the side walls of which a horizontal drum is mounted in the bearings, in which one end of the winding hose is fixed, connected to a fan or ventilation system, a gas inlet nozzle is attached to the other end of the hose for connecting and fixing on the exhaust pipe of the car and the drive for winding the hose onto the drum with fixing the position of the hose in the desired position, characterized in that the drive is made in the form of a balancing balancer, with of a cam mounted on the outer side of the cam body, the focus of which is rigidly fixed on the drum axis, and a vertically located air spring whose stem is directed away from the cam, a rotating pulley is fixed at the end of the rod, and the pulley and cam, on the outer side of which there is a flange, are bent the cable passing through the guide roller and wound around the cam when the hose is unwound, for which one end of the cable is mounted on the cam and the other on the outside of the housing after the cable passes through the pulley, with the poppy the minimum and minimum sizes of the cam shoulders are determined by the formulas: L _max ≥ (P ₁ + 3P ₂ ) R / k / 2; L _min ≥ (P ₁ + 5P ₂ ) R / 2k / 2, where P ₁ - the weight of the gas nozzle, kg; P ₂ - the weight of one meter of a hose, kg; k is the stiffness (elasticity) of the air spring, N / m; R is the radius of the drum, m; L _max - maximum cam shoulder, m; L _min - minimum cam shoulder, m. 2. The inertial drum according to claim 1, characterized in that the cam is in the form of an ellipse, the focus of which is located on the axis of symmetry in its center. 3. The inertial drum according to claim 1, characterized in that the cam has the shape of an ovoid, the focus of which is located on the axis of symmetry in the center of a smaller radius. 4. The inertial drum according to claim 1, characterized in that the cam has the shape of an equilateral triangle with rounded corners, the focus of which is located in its center. 5. The inertial drum according to any one of claims 1 to 4, characterized in that the balancer consists of several pneumatic springs having a rotating pulley at the end of the rod and installed parallel and pairwise opposite to each other, the pulleys of which are sequentially bent by a cable, while the required number of pneumatic springs is determined according to the formula: N = nL / 2L ₁ , where L is the length of the forming surface of the cam, mm; L ₁ - the maximum stroke of the pneumatic spring rod, mm; 2L ₁ - the length of the cable wound around the cam at maximum compression of the air spring, mm; n is the number of revolutions of the drum (for winding the required length of the hose); N - the required number of air springs, pcs.

Images