RU2187236C1 - Vacuum cleaner - Google Patents

Abstract

FIELD: cleaning equipment. SUBSTANCE: vacuum cleaner has device for removal of contaminants from gas flow and fan, which are positioned in gas flow channel, and recuperative heat-exchanger with at least one channel for gas to be heated and with at least one channel for cooled gas, both channels of recuperative heat- exchanger being communicated with gas flow channel. EFFECT: increased efficiency and reduced power consumption for disinfecting air in vacuum cleaner. 41 cl, 14 dwg

Description

 The invention relates to cleaning agents, and more specifically relates to a vacuum cleaner.

 Millions of people suffer from allergies, asthma and other diseases caused by ticks, germs and bacteria that live in carpets, upholstered furniture, and textile products used indoors.

 Dust containing mites, as well as bacteria and microbes, is sucked in by a vacuum cleaner during cleaning of various surfaces, however, most of these microorganisms enter the room together with the air discharged from the vacuum cleaner. In addition, the dust collected in the dust collector of the vacuum cleaner, in combination with the heat generated by the engine of the vacuum cleaner, and the moisture contained in the air, are a favorable environment for the growth and reproduction of various fungi and other microorganisms harmful to human health.

A known vacuum cleaner (KR 94-713, MKI A 47 L 9/28) containing a device for cleaning the gas stream from impurities and a fan. Air flowing from a vacuum cleaner to the atmosphere is heated by a heater. However, the use of a heater requires a large expenditure of electricity, especially at the maximum air flow through the vacuum cleaner, when the gas heating due to the fan is insignificant (10-20 ^o C) and, therefore, to heat the gas to 70-100 ^o C, a power heater is required, several times the fan power.

 Known vacuum cleaner (DE 4203712 A1), containing a device for cleaning the gas stream from impurities (filter) and a fan. In this vacuum cleaner, part of the air heated by the fan is returned to the gas stream in front of the filter, which also requires large energy expenditures and, in addition, limits the throughput of the vacuum cleaner in terms of air flow.

 The present invention is based on the task of developing a vacuum cleaner, the constructive implementation of which would reduce the power consumption spent on neutralizing air in it.

 The problem is solved in that the vacuum cleaner containing a device for cleaning the gas stream from impurities and a fan located in the channel for the gas flow, according to the invention further comprises a regenerative heat exchanger with at least one channel for the heated gas and at least one channel for the cooled gas communicated with the channel for the gas flow.

 The use of a recuperative heat exchanger allows you to return the heat released during operation of the fan into the channel for the gas flow and thereby obtain a zone of high temperatures in the section of this channel located after the channels of the heat exchanger for the heated gas.

 In one embodiment of the proposed vacuum cleaner in the direction of gas movement, a device for cleaning the gas stream from impurities, a channel for a heated gas, a fan and a channel for a cooled gas are sequentially arranged. This arrangement of the elements of the vacuum cleaner allows you to maximize the power supplied to the fan to create a high-temperature zone.

 It is advisable that, with the above arrangement of the elements of the vacuum cleaner, it would additionally contain at least one gas heater, which would be installed electric heater, while the gas heater can be installed either after leaving the channel for the heated gas, or before entering the channel for cooled gas.

 In other embodiments of the vacuum cleaner in the direction of gas movement, a device for cleaning the gas stream from impurities, a fan, a channel for a heated gas, a gas heater and a channel for a cooled gas are arranged in series. This arrangement of the elements of the vacuum cleaner is preferable when, for structural reasons, the zone of highest temperatures should be removed from the fan.

 The following sequential arrangement of vacuum cleaner elements in the direction of gas movement is also possible: a device for cleaning the gas stream from impurities, a channel for a heated gas, a gas heater, a channel for a cooled gas and a fan.

The vacuum cleaner may contain at least one additional device for cleaning the gas stream from impurities, which, depending on the above options for the sequential arrangement of the vacuum cleaner elements, can be placed before or after the fan, before or after the gas heater, or after the cooling gas channel. Various options for placing an additional device for cleaning the gas stream from impurities are due to design requirements (ease of layout, element sizes, minimal noise, etc.)
The gas heater may be equipped with a gas temperature regulator at its outlet.

 In addition, for simplicity and space saving, a gas heater can be installed in the channel for the heated gas and / or in the channel for the cooled gas.

 The inner surfaces of the channels of the recuperative heat exchanger and the channel for the gas flow are coated with a surface-active material that destroys microorganisms, for example, from salts or metal oxides.

The total area F _{1 of the} surfaces separating the channels for the heated and cooled gases is chosen such that F ₁ / F ₂ > 5, where F ₂ is the total cross-sectional area of the channels for the heated and cooled gases of the regenerative heat exchanger. When this ratio is fulfilled, it is possible to ensure effective heat transfer between the heated and cooled gas in the heat exchanger.

 The recuperative heat exchanger can be located in a single housing with a fan and a device for cleaning the gas stream from impurities or in a separate attachment connected to the channel for the gas flow.

 Since the heat fluxes in the recuperative heat exchanger are negligible, it can be made of plastic or fiberglass.

In the future, the invention is illustrated by specific examples of its implementation and the accompanying drawings, in which:
FIG. 1 depicts a General view of the vacuum cleaner with the location of its elements according to one of the options;
FIG. 2-7 - various sequential arrangement of the elements of the vacuum cleaner;
FIG. 8 is a diagram of a vacuum cleaner with gas heaters in the channels of a regenerative heat exchanger;
Figures 9-10 are diagrams of a vacuum cleaner with a different arrangement of a device for mixing air from the atmosphere and a device for discharging air into the atmosphere;
FIG. 11 is a section AA in FIG. 1;
FIG. 12 - node In on an enlarged scale;
FIG. 13 is a general view of a regenerative heat exchanger;
FIG. 14 is a diagram of a vacuum cleaner with a regenerative heat exchanger placed in a separate console.

 The vacuum cleaner according to the invention comprises a device 2, for example, a filter, installed in the housing 1 (FIG. 1), for cleaning the gas stream entering the vacuum cleaner from mechanical and liquid impurities, a gas duct 3, a fan 4 and a regenerative heat exchanger 5 s for at least one channel 6 for the heated gas and one channel 7 for the cooled gas. The number of channels 6 and 7 of the heat exchanger can be different and depends on the fan power and the flow rate of the pumped gas. The sequential arrangement of the elements of the vacuum cleaner in the direction of gas movement may be different. For example, in FIG. 2 shows a diagram in which, in the direction of gas movement, a device 2 for cleaning a gas stream, a channel 6 for a heated gas, a fan 4 and a channel 7 for a cooled gas are arranged in series. The vacuum cleaner may also contain at least one heater 8, which for a given arrangement of the elements of the vacuum cleaner can be placed before or after fan 4 (figure 3 or 4).

 The device 2 for cleaning the gas stream and the fan 4 (figure 5) can be installed in front of the channel 7 for the cooled gas, in this case, the heater 8 is placed at the outlet of the channel 6 for the heated gas.

 In FIG. 6 is a diagram in which a device 2 for cleaning a gas stream, a channel 6 for a heated gas, a heater 8, a channel 7 for a cooled gas and a fan 4 are sequentially installed in the direction of gas movement.

 As the heater 8, an electric heater is used, which can be equipped with a gas temperature regulator at its outlet.

 The vacuum cleaner may also contain an additional device 9 (Fig.7) for cleaning the gas stream from impurities, which, depending on the sequential arrangement of the elements of the vacuum cleaner, can be placed before or after fan 4 (Fig.7a, b, f, s, and, m , y), before or after heater 8 (FIG. 7g, d, k, o, n, s, p), or after channel 7 (FIG. 7c, g, l, p, t) for the gas to be cooled.

 In FIG. 8 shows a diagram of a vacuum cleaner in which heaters 8 are placed in channels 6 and 7 of heat exchanger 5. If two or more channels 6 and 7 are used in heat exchanger 5, heaters 8 are installed in each channel.

 The vacuum cleaner may include a device 10 (Fig. 9) for mixing air from the atmosphere, which, with any arrangement of elements of the vacuum cleaner, is placed before entering the fan 4, and a device 11 (Fig. 10) for discharging air into the atmosphere, installed after exiting the fan 4.

The channels 6 and 7 of the heat exchanger 5 (Fig. 11-13) are separated from each other by partitions 12, while the total surface area F _{1 of} the partitions 12 separating the channels 6 and 7 for the heated and cooled gases is selected such that F ₁ / F ₂ > 5, where F ₂ is the total cross-sectional area of channels 6 and 7 for heated and cooled gases. The inner surfaces of the channels 6 and 7 of the heat exchanger 5 and channel 3 for the gas flow are coated with a surface-active material that destroys microorganisms.

 As shown in FIG. 1, a device 2 for cleaning the gas stream from impurities, a fan 4 and a recuperative heat exchanger 5 are placed in one housing 1. however, the recuperative heat exchanger can be placed in a separate box 12 (Fig. 14) together with a device 2 for gas purification from impurities.

 The proposed vacuum cleaner operates as follows.

 Suction gas, such as air, together with impurities (mechanical and liquid) enters the device 2 (Fig. 1) for cleaning the gas stream, which is a filter or separator. The gas heated in the fan is passed through a recuperative heat exchanger 5 through the channel 7 for the cooled gas, and through the channel 6 for the heated gas, gas is pumped to the inlet of the fan 4.

When the power N _{1 of the} fan 4, the flow rate G of the gas pumped through it, the heat capacity C _{p of the} gas, the temperature of the gas during the passage of the fan 4 rises by Δ ₁ equal to
Δ ₁ = N ₁ / (G • C _p ) (1)
When gas passes through channel 6 (channels) of the heat exchanger for the heated gas, the gas temperature will increase by
Δ ₂ = N ₂ / (G • C _p ) (2),
where N ₂ is the heat transfer capacity provided by the heat exchanger 5. The value of N ₂ can be calculated from the conditions:
N ₂ = G • C _p (t ₂ -t ₁ ) = G • C _p (t ₄ -t ₃ ) (3),
where t ₂ , t ₁ are the gas temperatures at the inlet and outlet of the channel 7 for the cooled gas of the heat exchanger 5, t ₄ , t ₃ are the gas temperatures at the inlet and outlet of the channels 6 for the heated gas of the heat exchanger 5, respectively.

The gas temperature at the entrance to the channels 7 for the cooled gas will be
t ₂ = t ₃ + Δ ₁ + Δ ₂ (4),
and the gas temperature at the outlet of channel 6 for the heated gas will be
t ₁ = t ₃ + Δ ₁ (5)
Relations (4) - (5) obviously follow from the law of conservation of energy.

The value of N ₂ (and therefore Δ ₂ ) is determined by the design of the heat exchanger 5 (for an ideal heat exchanger it can be arbitrarily large).

As follows from relation (4), even without additional heating of the gas (as is done in the prototype), by choosing the design of the heat exchanger 5, it is possible to provide a large value of t ₂ sufficient to kill bacteria in the vacuum cleaner path after fan 4.

In the case when the design of the heat exchanger cannot provide values of t ₂ sufficient for the destruction of bacteria (especially in infectious hazardous areas), additional heating of the gas is applied before it is supplied to the channels 7 for the cooled gas using a heater 8. Moreover, the power of this heater 8 will be several times smaller than in the prototype (in the formula (1) in this case, under N ₁ should take the total power of the fan 4 and heater 8).

 Additional gas heating can also be carried out in the channels 6 and 7 of the heat exchanger 5 by installing heaters 8 in them.

 To ensure a higher degree of gas purification in the vacuum cleaner before or after the fan, before or after the heater, or after the channels of the heat exchanger for the gas to be cooled, an additional device for cleaning gas from impurities can be installed 9. The choice of installation location for an additional device for cleaning gas from impurities is determined by the design requirements, such as ease of layout, minimal noise, etc.

To prevent overheating of the construction elements of the vacuum cleaner, it is possible to apply gas heating control to maintain the gas temperature at the heater outlet t in the range T ₁ <t <T ₂ , where T ₁ is a temperature sufficient to guarantee the destruction of microorganisms and bacteria, and T ₂ - the highest value of the gas temperature at the outlet of the heater, permissible for continuous operation of the design of the vacuum cleaner.

To prevent overheating of the gas, it is possible to mix cold gas from the atmosphere in a controlled manner until it enters the fan 4 and maintain a temperature t ₂ at the entrance to the channels 7 for the gas to be cooled in the range T ₁ <t ₂ <T ₂ . (Fig.9).

It is also possible to regulate the removal of part of the heated gas stream or the entire stream into the atmosphere, bypassing the channels 7 for the cooled gas of the heat exchanger and maintaining the gas temperature after the fan t ₅ in the range T ₁ <t ₅ <T ₂ (see Fig. 10).

When the values of the regulated temperature t of the gas stream in the intervals T ₁ > t or t> T ₂ , the power supply of the vacuum cleaner and heater 8 is disconnected.

Claims (41)

 1. A vacuum cleaner containing a device for cleaning the gas stream from impurities and a fan located in the channel for the gas flow, characterized in that it further comprises a recuperative heat exchanger with at least one channel for the heated gas and at least one channel for the cooled gas, in communication with the channel for the gas flow.  2. The vacuum cleaner according to claim 1, characterized in that in the direction of gas movement, a device for cleaning the gas stream from impurities, a channel for a heated gas, a fan and a channel for a cooled gas are arranged sequentially.  3. A vacuum cleaner according to any one of claims 1 and 2, characterized in that it further comprises at least one gas heater.  4. The vacuum cleaner according to claim 3, characterized in that an electric heater is installed as a heater.  5. A vacuum cleaner according to any one of claims 3 and 4, characterized in that the gas heater is installed after leaving the channel for the heated gas.  6. A vacuum cleaner according to any one of claims 3 and 4, characterized in that the gas heater is installed in front of the entrance to the channel for the cooled gas.  7. The vacuum cleaner according to claim 1, characterized in that it further comprises a gas heater, wherein, in the direction of gas movement, a device for cleaning the gas stream from impurities, a fan, a channel for a heated gas, a gas heater and a channel for a cooled gas are arranged in series.  8. The vacuum cleaner according to claim 1, characterized in that it further comprises a gas heater, wherein, in the direction of gas movement, a device for cleaning the gas stream from impurities, a channel for a heated gas, a gas heater, a channel for a cooled gas and a fan are arranged in series.  9. The vacuum cleaner according to claim 2, characterized in that it contains at least one additional device for cleaning the gas stream from impurities.  10. The vacuum cleaner according to claim 9, characterized in that the additional device for cleaning the gas stream from impurities is installed to the fan.  11. The vacuum cleaner according to claim 9, characterized in that an additional device for cleaning the gas stream from impurities is installed after the fan.  12. The vacuum cleaner according to claim 9, characterized in that the additional device for cleaning the gas stream from impurities is installed after the channel for the cooled gas.  13. The vacuum cleaner according to claim 5, characterized in that it contains at least one additional device for cleaning the gas stream from impurities.  14. The vacuum cleaner according to item 13, wherein the additional device for cleaning the gas stream from impurities is installed in front of the gas heater.  15. The vacuum cleaner according to item 13, wherein the additional device for cleaning the gas stream from impurities is installed after the gas heater.  16. The vacuum cleaner according to item 13, wherein the additional device for cleaning the gas stream from impurities is installed after the fan.  17. The vacuum cleaner according to item 13, wherein the additional device for cleaning the gas stream from impurities is installed after the channel for the cooled gas.  18. The vacuum cleaner according to claim 6, characterized in that it contains at least one additional device for cleaning the gas stream from impurities.  19. The vacuum cleaner according to claim 18, characterized in that an additional device for cleaning the gas stream from impurities is installed in front of the fan.  20. The vacuum cleaner according to claim 18, characterized in that an additional device for cleaning the gas stream from impurities is installed after the fan.  21. The vacuum cleaner according to claim 18, characterized in that the additional device for cleaning the gas stream from impurities is installed after the gas heater.  22. The vacuum cleaner according to claim 18, characterized in that an additional device for cleaning the gas stream from impurities is installed after the channel for the cooled gas.  23. The vacuum cleaner according to claim 7, characterized in that it contains at least one additional device for cleaning the gas stream from impurities.  24. The vacuum cleaner according to item 23, wherein the additional device for cleaning the gas stream from impurities is installed after the fan.  25. The vacuum cleaner according to item 23, wherein the additional device for cleaning the gas stream from impurities is installed in front of the gas heater.  26. The vacuum cleaner according to item 23, wherein the additional device for cleaning the gas stream from impurities installed after the gas heater.  27. The vacuum cleaner according to item 23, wherein the additional device for cleaning the gas stream from impurities is installed after the channel for the cooled gas.  28. The vacuum cleaner according to claim 8, characterized in that it contains at least one additional device for cleaning the gas stream from impurities.  29. The vacuum cleaner according to claim 28, wherein the additional device for cleaning the gas stream from impurities is installed in front of the gas heater.  30. The vacuum cleaner according to claim 28, wherein the additional device for cleaning the gas stream from impurities is installed after the gas heater.  31. The vacuum cleaner according to claim 28, characterized in that an additional device for cleaning the gas stream from impurities is installed after the channel for the cooled gas.  32. The vacuum cleaner according to claim 28, wherein the additional device for cleaning the gas stream from impurities is installed after the fan.  33. A vacuum cleaner according to any one of claims 1 to 32, characterized in that it further comprises a device for mixing air from the atmosphere, located before the fan enters.  34. The vacuum cleaner according to p. 33, characterized in that it further comprises a device for discharging air into the atmosphere, installed after exiting the fan.  35. A vacuum cleaner according to any one of claims 3 to 8, 14-32, characterized in that the gas heater is equipped with a gas temperature regulator at its outlet.  36. A vacuum cleaner according to any one of claims 3, 4 and 35, characterized in that the gas heater is installed in at least one channel for the heated gas and / or in one channel for the cooling gas.  37. A vacuum cleaner according to any one of claims 1 to 36, characterized in that the inner surfaces of the channels of the regenerative heat exchanger and the channel for the gas flow have coatings of a surface-active material that destroys microorganisms. 38. A vacuum cleaner according to any one of claims 1 to 37, characterized in that the total area F _{1 of the} surfaces separating the channels for the heated and cooled gases is selected such that F ₁ / F ₂ > 5, where F ₂ is the total cross-sectional area channels for heated and cooled gases recuperative heat exchanger.  39. A vacuum cleaner according to any one of claims 1 to 38, characterized in that the regenerative heat exchanger, fan and device for cleaning the gas stream from impurities are located in a single housing.  40. A vacuum cleaner according to any one of claims 1 to 38, characterized in that the recuperative heat exchanger is placed in a separate prefix to the vacuum cleaner connected to the channel for gas flow.  41. A vacuum cleaner according to any one of claims 1 to 40, characterized in that the recuperative heat exchanger is made of plastic or fiberglass.

Images