SU1595455A1 - Vacuum cleaner - Google Patents

Abstract

This invention relates to the field of dust collection. The purpose of the invention is to increase the performance and efficiency of sound attenuation. The vacuum cleaner includes a housing with a lid, a dust collector, a fan with a perforated outlet, an electric motor associated with a belt drive fan and louvers for air to escape. The housing consists of compartments for a dust collector, a fan with an engine and a belt drive, respectively. Outlet ports face the engine. The engine compartment is equipped with a sound absorbing cover. The belt drive compartment is a sealed chamber with inlet and outlet openings, the cavity of which is connected to the cavity of the compartment for the engine and the fan. 4 hp f-ly, 7 ill.

Description

This invention relates to a dust harvesting technique, in particular to industrial vacuum cleaner designs.

The purpose of the invention is to increase the productivity and efficiency of the sweltering agent.

FIG. 1 shows a vacuum cleaner, side view; in fig. 2 - the same, top view; in fig. 3 - outlet of the vacuum cleaner; in fig. 4-7 shows variants of noise-suppressing elements of the outlet nozzle.

The vacuum cleaner consists of a housing 1 located on wheels 2 and 3, a cover 4 with an inlet 5 and a hose 6, a handle 7; Inside the case, a fan 8 is disposed with a perforated outlet 9, an electric motor 10 connected to the fan with a belt drive 11, and a louver 12 for air outlet. The housing consists of compartments 13–15, respectively, for a dust collector, a fan with an engine, and a belt drive. The holes 16 of the outlet 9 are cut in the direction of the engine 10 for cooling by blowing. Airflow can be two-sided, if the holes 16 are oriented along the axis of the engine. The engine compartment 14 is provided with a sound-absorbing housing 17 and functions as a chamber silencer. The belt drive compartment 15 is a sealed chamber with an inlet 8 and an outlet 19, and serves as a reactive silencer.

The outlet nozzle 10 consists of an active part, for example, in the form of a spiral channel 20 with an opening angle equal to the opening angle of the fan cochlea and lined with sound absorbing material 21, and the resonance part. The latter has a means for adjusting the resonant frequency and air flow depending on the rotational speed of the fan and consists of a piston 22 with perforation 23, the rod of which is connected to the piston stroke adjustment knob (Fig. 3).

FIG. 4 shows an embodiment of an outlet nozzle 10, the active part of the noise suppressor of which consists of a plate 24, horizontally arranged along the diameter of the nozzle 10 and lined with sound

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with the absorbing material 21. Opposite to the exit of the cochlea of the fan, in the plate 20 there is a hole 25 for the passage of air on both its sides. The resonant part of the noise silencer is made in the form of a coaxially located body 10 of the outlet nozzle of the sleeve 26. The piston of the resonator frequency and air flow setting means is made in the form of a ring 27 fixed in the sleeve 26 by means of screws 28 and the nozzle encompassing the housing from the outside. The sleeve 26 and the piston 27 form a resonant cavity 29, which is a Helmholtz resonator with a throat, the functions of which are performed by the holes 16 located on the left side of the shaft 27, the remaining holes serve for exhaust.

FIG. 5, 6 and 7 depict an embodiment of a silencer with an active part in the form of a sinusoidal metal insert 30, lined with sound-absorbing material 21, and attached at one end to the body 10 of the nozzle. The resonator silencer part is tuned by a U-shaped bracket 31 rigidly connected to a movable piston 27, which is spring-loaded spring 32 relative to the body of the outlet nozzle 0. In the middle of the U-shaped bracket there is a threaded element, for example, a nut 33, which includes a threaded rod 34, movably supported in the body of the vacuum cleaner 1. With the strings 35, the outlet 10 is attached to the body of the vacuum cleaner.

The vacuum cleaner works as follows. When the electric motor 10 is turned on through the V-belt transmission, the blades of the fan 8 begin to rotate. As a result of the vacuum, the air is sucked through the hose 6 and the inlet 5 and enters the fiber collector. After the fan, air enters the outlet 9, where it passes through a spiral channel lined with sound-absorbing material 21 with an opening angle equal to the opening angle of the fan scroll. Due to this, a significant sound absorption occurs due to the dissipation of sound energy in the pores of the sound-absorbing material.

An expanding spiral channel with an opening angle equal to the opening angle of the fan scroll reduces the pressure loss at the outlet, which consequently increases the efficiency of the vacuum cleaner.

Then the air enters the resonant chamber, cut off by a perforated plate. 22, where the sound part is damped

energy.

The volume of the resonant chamber is controlled by the stroke of the piston 22 by rotating the handle located on the body of the vacuum cleaner. By changing the volume of the resonant chamber, you can adjust the change in intake air flow

into the vacuum cleaner and adjust it to the desired frequency range, gushing the resonator. The air through the holes 16 gets on the electric motor 10, which cools down, and an increased pressure is created in the internal cavity of the vacuum cleaner, which causes dust to enter there.

The aerodynamic design of the vacuum cleaner is organized in such a way that the individual cavities act as silencers. For example, the closed cavity 14 is a chamber silencer whose entrance channel serves as apertures 16, and exit aperture - blinds 12. Sound energy is absorbed by layers of sound absorbing material located along the perimeter of the casing 17.

A sealed chamber 15 with an inlet 18 and an outlet 19 orifices, enclosing a belt drive connecting the motor 10 to the fan 8, performs the function of a reactive silencer noise that transmits sound below the cut-off frequency, for example, that is equal to the frequency of the fan blade noise of the order 1000 Hz, and prevents the spread of 25 sound vibrations, the frequency of which is above the limit.

In embodiments of the outlet nozzle 10 (FIG. 4-7), the active part of the silencer operates in a manner similar to that shown in FIG. 3, taking into account the manufacturability of its constituent elements.

The resonant part of the outlet 10 is constructed in such a way that, depending on the fan speed, its parameters change simultaneously: 35 volume of the resonant chamber 29 and effective area of the resonator neck (holes 16 located on the left side of the piston 27), as well as air flow through the holes 16 located on the right side of the piston. For example, increasing the fan speed increases the frequency of the blade noise created by the blades of the wheel and, therefore, the volume of the resonant chamber must be less, while the air flow rate increases. This situation is resolved by moving the piston 27 to the left, while the chamber 29 is reduced in volume and the exhaust ports 16 are released, i.e. an increase in the air flow. The piston 27 can be fixed in a certain position either by screws 28 in the slots

50 sleeves (Fig. 4), or by moving the U-shaped bracket 3 by screw pair 33 and 34 (Fig. 5).

When a sound wave is incident on an oscillating system with attenuation, which is represented by a resonant chamber 29 with a hole of 5 to 16 on the left side of the piston 27, it is excited and takes away acoustic energy from the sound wave at frequencies close to the resonator's natural frequency,

that is, absorption of sound energy occurs in a narrow frequency range.

Claims (5)

1. A vacuum cleaner comprising a housing with a lid, a vacuum cleaner, a fan with a perforated outlet pipe, an electric motor associated with a belt drive fan, and an air outlet louver, characterized in that, in order to improve performance and efficiency, the housing consists of compartments for a dust collector, a fan with an engine and a belt drive, respectively, with the outlet ports facing the engine, the compartment for accommodating the engine is equipped with a sound-absorbing casing, and the compartment for mennoy transmission is a sealed chamber with inlet and outlet openings, wherein a cavity associated with the cavity for the engine compartment and the fan. 2. The vacuum cleaner according to claim 1, wherein the outlet port consists of active and resonant parts, the latter having a means to adjust the resonant frequency and air flow depending on the speed of rotation of the fan. 3. The vacuum cleaner according to claim 2, characterized in that the active part of the outlet pipe is made in the form of a spiral channel with an opening angle equal to the opening angle o fan snails equipped with a sound-absorbing coating, the means for adjusting the resonant frequency and air flow is made in the form of a perforated plate, the stem of which has means for moving it in the form of a handle, and the resonator part of the outlet nozzle is a cavity bounded by the case of the output nozzle and the outer wall of the porshn. 4. The vacuum cleaner according to claim 3, characterized in that the active part of the outlet nozzle is made in the form of a plate horizontally disposed along the diameter of the nozzle with an opening located opposite the outlet 5 of the cochlea, having a sound-absorbing coating on both sides, and the resonator part is made in the form of a sleeve located coaxially, the piston of the resonator frequency and air flow setting means is made in the form of a katsea fixed in the sleeve by screws and covering the body of the connection from the outside. 5. Vacuum cleaner pop. 1, characterized in that the active part of the outlet nozzle is made in the form of a metal insert in the form of a sinusoid, covered with sound-absorbing material and attached at one end to the body of the nozzle, and the means for moving the body consists of a U-shaped bracket, spring-loaded relative to 0 end of the outlet pipe and installed on the threaded rod. 0 Figg Ib 22 Fig.Z 27 w fig l 31 i n, J4 Phage. five / l- / i FIG. 6 FIG. 7