CZ35651U1 - Multi-stage filter unit of an air filtration system - Google Patents

Description

Multi-stage filter unit of the air filtration system

Field of technology

The technical solution concerns a multi-stage filter unit of an air filtration system with a fully automatic exchange of filters in individual stages on the basis of continuous evaluation of the quality of flowing air in each part separately.

State of the art

In the current situation of general environmental pollution and air quality requirements in public spaces and households, existing air filtration systems, even in complex air handling units, are still based on trivial manual replacement of filters, placed here in fixed frames, mostly within set deadlines, regardless of their current clogging and pollution. The intervals of these replacements usually do not correspond to the situation of heavy filter contamination. At the same time, the dirt is released from the clogged filters during operation and enters the air system, so that the clogged filters cease to fulfill their purpose and, in addition, de facto cause greater resistance to the intake air. As a result, the intake air flowing through the dirt-filled filters entrains dust and allergen particles, and these then enter the ventilated, filter-protected areas.

The essence of the technical solution

These shortcomings are eliminated by a multi-stage air filtration unit comprising a rectangular pipe in which the individual filter stages are located, according to this technical solution, the essence of which is that each filter stage consists of two tanks located outside the pipe, of which at least one is equipped with a winding mechanism of sliding filter belts, which are arranged between the magazines and provided on the reinforced edges of the window for optical gates to measure the displacement of these filter belts. Each filter stage is equipped with differential pressure sensors and an air quality sensor is further arranged behind the first basic filter belt and the third filter stage is equipped with odor and toxin sensors. The first filtration stage comprises a basic filter belt formed by a filter with a normal filter permeability, where the filter material is arranged on the surface along its entire length and the displacement of the belt here is unidirectional, since only one container is equipped with a winding mechanism. In the second filtration stage, where the sliding filter belt is provided alternately with at least one part with a dust filter and a fully permeable part, the movement of the filter belt is bidirectional, due to the fact that both tanks are equipped with a winding mechanism, as in the third filtration stage. the filter belt is alternately provided with at least one part with a filter material consisting of a carbon filter and a fully permeable part. The fourth stage, which provides protection against the ingress of unwanted gases and smoke, is preceded by a sensor of smoke, gases and annoying substances and also contains two magazines with winding mechanisms providing two-way seat belt movement with windows for the optical gate and parts made of impermeable and non-flammable blinds.

The present multi-stage filtration unit enables air filtration with fully automatic filter exchange in individual filtration stages on the basis of continuous evaluation of the quality of flowing air in each part separately. It evaluates and currently fully automatically responds according to the settings from the user to the current air pollution, which it registers with the installed sensors of dust, odors, gases, etc. Specific filters change automatically according to the status of these sensors.

- 1 CZ 35651 UI

For proper operation, it is advantageous here if the dust filter of the second filter belt consists of a HEPA or nano filter.

Clarification of drawings

The technical solution will be explained in more detail with the help of the drawings, where in Fig. 1 the multi-stage filter unit of the air filtration system is in a schematic axonometric embodiment. Giant. 2 shows a basic filter belt of the first filtration stage with a filter with conventional filter permeability, and FIG. Similarly, Fig. 4 shows a third filter belt with carbon filter parts and fully permeable parts. Fig. 5 shows a segment of a seat belt with a permeable part and a part made of an impermeable and non-flammable blind.

Examples of technical solutions

The multi-stage filter unit of the air filtration system, see FIG. located outside the rectangular pipe 14, where only one of the reservoirs 10 is provided by the winding mechanism 9. The displacement 12 of the basic filter belt 1, see Fig. 2, in which the filter material 15 with normal filter permeability is arranged on its surface along its entire length, takes place. so only one way. The optical gate 11 measuring displacement 12 arranged here, thanks to the windows 1U located on the reinforced edge 16 of the basic filter belt 1, guarantees the precise displacement and positioning of the basic filter belt 1 with regard to the identification of the degree of contamination. By strengthening the edges 16 of the basic filter belt 1, greater strength and stability of said windows 1E is achieved. The differential pressure sensor 5 measures and compares the air pressure in front of and behind the basic filter belt. The differential pressure sensor 5, which is set according to the user's needs and requirements, then evaluates the degree of clogging of the basic filter belt 1 and the system either leaves the basic filter belt 1 in the same position or moves its dirty part into the tank 10. In order to prevent any possible contamination during the transfer of the basic filter belt 1 to the air-conditioning system, the second filter belt 2, consisting of either a HEPA or a nano filter, is moved out of the second filtration stage for this time.

The device independently measures and registers with its optical gate 11 and windows 1E on the basic filter belt 1 its unwinding and notifies the operator in advance of its end. These facts can also be solved via remote access, so that the user or service worker has an up-to-date overview of the stock status of the clean basic filter belt 1 and the possible need to replace it.

Improved filtration is further ensured by the following second stage, where the second filter belt 2, see Fig. 3, contains parts of a dust filter 17, i.e. a HEPA or nano filter, with a minimum efficiency of 99.97%, capable of capturing microscopic dust particles and allergens. while also acting as a support in the replacement of the basic filter belt 1 in the first stage. The second stage of filtration works similarly, with the difference that the displacement 12 of the second filter belt 2 is bidirectional here, so both hoppers 10 are provided with a winding mechanism 9 to ensure the displacement 12 of the second filter belt 2 back and forth.

Although the air stream 13 leaving the first filtration stage is filtered through the base filter belt 1, however, if the outside air contains said microscopic contaminant particles passing through it, in the second filtration stage, after detection of these microparticles by the air quality sensor 6, part dust filter 17. i.e. HEPA or nano filter, from reservoir 10

-2 CZ 35651 UI and to capture them. However, the second filter belt 2 is not formed by a single continuous HEPA or nano filter, but after a certain length of the section 18 it is fully permeable, without any filter elements. This is followed by a part of the HEPA or Nano filter, or two parts of the HEPA or Nano filter can be arranged one after the other, followed by a completely permeable part 18. The reason is that if the quality of the outdoor intake air improves, it records according to the required setting The sensitive sensor 6 of the dust microparticles, and no further cleaning of the air is required, replaces the HEPA or nano filter part on the second filter belt 2 with the fully permeable part 18. This saves part of the HEPA or nano filter. The system remembers which part of the second filter belt 2 was last used and what its current contamination is, and if this part can be reused, it will use it again at the earliest opportunity. The reinforced edge 16 of the second filter strip 2, as with the first filter strip 1, ensures its greater strength and stability of the optical gate detection IE windows I1, ensuring precise displacement and positioning of the respective part of the second filter strip 2 with contamination identification. If the HEPA or nano filter becomes clogged, which is again evaluated by the differential pressure sensor 5, another clean part of the HEPA or nano filter is ejected. The system is programmed and the displacement 12 of the second filter belt 2 is controlled by the optical gate 11 so that the air behind said filter belts 1 and 2 is clean at all times according to the settings. Air quality is measured here all the time. And as in the first stage, the operator is continuously informed about the current state of the rest of the second filter belt 2.

The third filtration stage ensures the filtration of odors, toxins and gaseous pollutants, which are detected, evaluated and compared by odor sensors 7, through the filter part of the carbon filter 19 of the third filter belt 3, see Fig. 4, containing activated carbon which absorbs odors and toxic substances. . The bidirectional displacement 12 and the arrangement of the third filter belt 3 in the hoppers 10 equipped with the winding mechanisms 9 is the same as in the second filtration stage. The third filter belt 3 is formed by at least one part of the carbon filter 19 and the adjoining fully permeable part 20.1. In this case the filter belt 3 is provided with reinforced edges 16 for greater strength and stability. part 20 or carbon filter 19 with pollution identification. Again, if the carbon filter 19 is clogged or no filtration is required, which is evaluated by either the differential pressure sensor 5 or the odor sensors 7 by comparing the state before and after the carbon filter 19, a part of the third filter belt 3 is moved as needed. Even in this case, the displacement 12 is controlled by the optical gate 11.

Each filtration stage works independently of itself and can thus be used separately.

The fourth stage provides safety protection against the ingress of unwanted gases and smoke into the protected area. It consists of a seat belt 4, see Fig. 5, comprising a part made of impermeable and non-flammable blind 21 and a part fully permeable, which is, as in the case of the second and third filtration stage, arranged in two tanks 10 equipped with winding mechanisms 9 for two-way movement. 12 in the event of a danger, such as a fire or the detection of heavy smoke in the intake air, or unwanted life-threatening gases detected by a smoke, gas and annoying sensor 8 located in front of the seat belt 4 itself, the fourth stage is blocked by pulling an impermeable and non-flammable blind 21 any intake and movement of air from the outside, thus shutting down the entire downstream system of the air handling unit. After the danger has passed, the impermeable and non-flammable roller blind 21 rolls into the magazine 10, whereby the completely permeable part 22 of the seat belt 4 is extended and the operation of the whole device is restored. Even in this case, the seat belt 4 has reinforced edges 16 for greater strength and stability of the detection windows JT arranged here by the optical gate 11, guaranteeing the precise displacement 12 and the location of the parts of the seat belt 4 in question.

Claims (2)

PROTECTION REQUIREMENTS A multi-stage filter unit of an air filtration system, comprising pipes of rectangular cross-section, in which individual filter stages are located, characterized in that each filter stage consists of two reservoirs (10) located outside the pipes (14), at least one of which is equipped a winding mechanism (9) of sliding filter belts (1, 2, 3) provided on the reinforced edges (16) of a window (1U) for optical gates (11) for measuring the displacement (12) of these belts (1, 2, 3) arranged between magazines (10), each filter stage being equipped with differential pressure sensors (5) and an air quality sensor (6) being further arranged behind the first basic filter belt (1) and the third filter stage being equipped with odor and toxin sensors (7), the first the filter stage comprises a basic filter belt (1) formed by a filter with normal filter permeability, where the filter substance (15) is arranged on the surface along its entire length and the displacement (12) of the basic filter belt (1) is unidirectional the winding mechanism (9) is equipped with only one container (10), while in the second filtration stage, where the sliding filter belt (2) is provided alternately with at least one part with a dust filter (17) and a part (18) fully permeable, the displacement ( 12) of the filter belt (2) bidirectional, since both reservoirs (10) are equipped with a winding mechanism (9) here, as in the third filtration stage, where the filter belt (3) is alternately provided with at least one part with a carbon filter (19) and the part (20) is fully permeable, the fourth stage, which forms the protection against the ingress of unwanted gases and smoke, has a smoke, gas and annoying sensor (8) upstream and also contains two containers (10) with winding mechanisms (9) providing bidirectional displacement (12) of the seat belt (4) with windows (1Γ) for the optical gate (11) arranged therein for measuring the displacement (12) of the seat belt (4) provided with the permeable part (22) and the impermeable and non-flammable roller blind part (21). The multi-stage filter unit of the air filtration system according to claim 1, characterized in that the dust filter (17) of the second filter belt (2) is formed by a HEPA or a nano filter.