CZ2019423A3 - A method of preventing the loss of differential pressure when opening a door and a system for this method - Google Patents

Abstract

The invention uses a dynamic air barrier acting perpendicular to the surface of the door (1) against static overpressure, which is formed by a directed dynamic flow (2) of air propagating on the side of the overpressure door (1) to prevent the loss of pressure difference when opening the door (1). horizontally from the top of the door (1), or vertically from at least one of the sides of the door (1), to the opposite end of the door (1). The invention also relates to a system comprising a device (5) for generating a directed dynamic air flow (2), a differential pressure sensor (6), a door status sensor (1), and a control unit connected or integrated in the operation and air output controller (5).

Description

A method of preventing loss of differential pressure when opening a door and a system for performing this method

Field of technology

The invention relates to the prevention of the loss of pressure difference between two structurally separate spaces which are mutually accessible via an open door.

Prior art

If there is a pressure difference between two separate spaces, the spaces within the pressure difference can always be referred to as the space with the initial pressure and as the space with overpressure or underpressure. If the rooms are connected by opening the door, the air flow will try to equalize the pressures between the two rooms to equilibrium. The effort to balance the pressure between two spaces with a prevailing pressure difference during their sudden connection is a natural manifestation of inanimate nature.

This natural manifestation of inanimate nature is in many cases undesirable for human effort and must be compensated.

One of the current examples of human endeavors, where the loss of the required overpressure must be avoided when opening a door, is the fire protection of buildings, namely the protection of a protected escape route from a building against smoke contamination. The escape route generally leads through the building to a door allowing the building to leave safely, the escape route area being supplied with fresh air which creates an overpressure in the escape route area which prevents smoke from reaching the escape route from the source of the fire. In the case of opening the door from the protected escape route out of the building for safe escape of persons at the same time, due to overpressure, air escapes from the protected escape route. This problem is currently solved by dimensioning the air handling unit to maintain the overpressure in the protected escape route at a much higher output in terms of fresh air supply so as not to lose the overpressure when the door is open from the protected escape route. At present, strict standards for the ventilation of protected escape routes, a minimum air overpressure of 10 Pa is required for the door opening in the protected escape route area to the outdoor environment into which the door opening opens, but at the same time the permissible overpressure of 50 Pa must not be exceeded. or 100 Pa depending on the situation.

The disadvantages of the solution with modified dimensioning of the air-conditioning device for maintaining overpressure in the area of the protected escape route are that for example for doors with an open area of 4 m ² and overpressure of 10 Pa there is a requirement for dimensioning of air conditioning in addition, an air output of approximately 10 m ³ / s. This is a challenging condition in terms of building design, both from an economic point of view and from the point of view of installation conditions, and last but not least from the point of view of maintenance. The air-conditioning system supplying the air-protected escape route must therefore be dimensioned for approximately twice the air output, and with it also all air-conditioning distributions, including the backup source of electrical energy.

Unfortunately, it is not possible to solve these disadvantages by means of automatic sliding doors or rotating turnstiles, which would continuously close the door opening against air leakage, because in the event of a crisis, regulations stipulate that doors or turnstiles open wide to clear the escape route. .

Another well-known current example of the use of a pressure difference between two structurally separated spaces connected by a door is clinically sterile operating theaters, which contain an overpressure of purified air to prevent contamination of the patient's body from the outside.

- 1 CZ 2019 - 423 A3 operating room space. Or further, for example, research laboratories or clean production facilities. Here, too, there is a requirement that the air handling unit be dimensioned for sudden fluctuations in the pressure difference when the door is opened. In addition, double doors are usually built, which create a certain transition space between them. The disadvantages of such a solution are that it is a constructionally and spatially demanding solution, that each use of the intermediate space means a pressure loss that the air conditioning system must complete, and last but not least, the use of the intermediate space slows down the transfer of people from one place to another.

The object of the invention is to provide a method which overcomes the above-mentioned disadvantages of the prior art by preventing the loss of pressure difference when the door is open, actively preventing the transfer of higher pressure air through the door to the initial pressure space. retain their throughput for persons and equipment. It is also part of the invention to provide a system that allows the method of the invention to be carried out.

The essence of the invention

The object is achieved by providing a method for preventing the loss of pressure difference when opening a door according to the invention below.

As part of the method of preventing the loss of pressure difference when the door is opened, the condition of the door is continuously monitored, whether it is opened, opened or closed.

The essence of the invention lies in the fact that on the side of the door with overpressure in front of the opening door an air barrier is formed from the directed dynamic air flow, which is maintained until the moment of closing the door.

The static pressure of the overpressure acts on the surface of the door, which at the moment of opening the door causes the movement of air from the overpressure through the door. It is advantageous if an air barrier is installed in the door, which acts at least at the same or higher dynamic pressure, which prevents air from escaping through the door. The air barrier acting perpendicular to the door surface is a component of a directed dynamic air flow, the creation of which requires less ventilation capacity than for pumping out the escaping air through the door with oversized ventilation devices to maintain overpressure.

An indisputable advantage of the invention is that, due to the reduction of the loss of pressure difference, the air handling unit does not have to be dimensioned for such an air output (m ³ / s) that would compensate for the pressure loss when opening the door. This brings significant economic, construction and operational benefits.

It is advantageous if the actual value of the pressure difference is measured, after which the intensity of the dynamic air flow and / or the direction of the dynamic air flow changes according to the currently measured value of the pressure difference. To further save resources, it is desirable that the method be performed not only in two states, on and off, but that it responds to current requirements to avoid overpressure losses. Since the air barrier is one of the components of the directed dynamic air flow, its parameters can be changed by the intensity of the flow and the angle that the dynamic air flow makes with the planar surface of the door. The change of parameters can be calculated using vector composition of components. Preferably, the direction of the dynamic air flow forms an angle in the range from 0 ° to 20 ° with the parallel planar surface of the door.

In another preferred embodiment of the method according to the invention, the beginning of the air flow is arranged horizontally above the door, or the beginning of the air flow is arranged vertically along at least one side of the door. Thanks to the arbitrary arrangement of the beginning of the air flow towards the door, it is possible to choose a wide range of construction solutions, both for new buildings and within the reconstruction of existing buildings.

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It is furthermore advantageous if the air is sucked in from the overpressure space or from the initial pressure space to form an air barrier. In case the air can be any, it is advantageous to suck from the space with the initial pressure, but if it is necessary for the air to maintain some operating parameters, eg temperature or purity, it is more suitable to suck it from the space with overpressure.

The invention also includes a system for carrying out the method of the invention to prevent the loss of pressure difference when the door is opened.

The system for carrying out the method for preventing the loss of differential pressure when the door is opened comprises at least one device for generating a directed dynamic air flow, and further the system comprises at least one differential pressure sensor between the spaces interconnected by the door.

The essence of the invention lies in the fact that the device is placed on the side of the door with the prevailing overpressure, so that the dynamic air barrier acts against the static overpressure. Further, the device is arranged horizontally above the door, or vertically at at least one side of the door, to propagate a directed dynamic air flow from the device toward the opposite end of the door so that the directed dynamic flow component forms an air barrier acting in a direction perpendicular to the door surface against static overpressure. in the entire area of the door. The system also includes a control unit to which a device for creating an air flow is connected to control the operation of the system. The control unit is connected to a differential pressure sensor, and further to at least one door status sensor.

The results of the system's operation lead to savings in economic costs, while the system is relatively simple in relation to the air conditioning equipment used so far. The system is well applicable to both new and existing buildings, including historic ones, which do not allow for very fundamental changes in architecture.

In a further preferred embodiment of the system according to the invention, the control unit is provided with at least one data storage for storing the control software module of the device operation, forming or being connected to the controller of the operation and air output of the device. This is advantageous if not only the system is switched on and off, but if it allows the air barrier to be adapted to the current state of affairs by adjusting the intensity and / or direction of the directed air flow.

It is advantageous if the air intake device is connected to a space with an overpressure and / or to a space with an initial pressure. Depending on the situation, suitable air can be used, eg in terms of parameters such as temperature, purity, etc.

In a preferred embodiment of the system according to the invention, the device is formed by an air curtain. This is very advantageous because air curtains can create a directed air flow with controlled intensity and direction. In addition, they are used to protect against heat leakage from rooms, so that their adaptation to prevent the loss of overpressure is more than appropriate, especially in emergency situations requiring protected escape routes.

The advantages of the invention include, in the first place, the saving of production and operating costs for air-conditioning systems for creating overpressure when the door is open, which otherwise have to be dimensioned to compensate for large pressure losses. The invention advantageously creates a dynamic back pressure which does not allow a loss of pressure, while the invention is simple, easy to manufacture and has low operating costs in view of the present solutions. In addition, it is possible to adapt the air curtains advantageously for the application of the invention, so that already installed solutions can be used, for example, in security systems.

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Explanation of drawings

The present invention will be further elucidated in the following figures, where:

Fig. 1 shows a cross-section of an object and a horizontal embodiment of the invention above a door, Fig. 2 shows a plan view of an object and a double-sided vertical embodiment of the invention at a door; of the invention above the door from the outside of the building, where there is a higher pressure.

Examples of embodiments of the invention

It is to be understood that the specific embodiments of the invention described and illustrated below are presented by way of illustration and not by way of limitation. Those skilled in the art will find, or be able to ascertain using routine experimentation, more or less equivalents to the specific embodiments of the invention described herein.

The protected escape route 12 of the building 8 shown in section in Fig. 1 and in plan view in Fig. 2 and Fig. 3 is separated from the outdoor space 4 by the initial pressure through the door L. The protected escape route 12 of the building 8 is usually supplied with ventilation air by a supply fan 7. of air into the protected escape route 12, which creates the required static overpressure of air in it. The dynamic component 9 represented by the directed air flow vector W4 shown by the vector W2 perpendicular to the door surface 11 emanating from the directed dynamic air flow generating device 5 generates a dynamic pressure which helps to maintain the desired static overpressure in the protected escape path 12 when the door 1 is opened. of air. If the door 1 is opened, the device 5 is activated, and if the door 1 is closed, the device 5 is switched off. The device 5 sucks air through the diffuser 10 from the initial air pressure space, in this embodiment from the exterior, or via the diffuser 11 from the overpressure space or from the interior.

The application shown in section in Fig. 1 is an example of an embodiment where the device 5 for creating a dynamic air stream 2 is installed in a horizontal position above the door 1. The device 5 is provided with a control unit which is integrated in the operation regulator of the device 5 for controlling the direction and intensity of the dynamic air flow 2. The control unit is connected to the differential pressure sensor 6, between the space 4 with the initial air pressure and the space 3 with the overpressure, i.e. with the protected escape route 12, and further the control unit is connected to the door condition sensor 1, which continuously monitors whether the door 1 open, open or closed. The control unit is provided with a data storage on which a software module is stored, which contains a program for calculating the angle and direction and intensity of the produced directed dynamic air stream 2 from the device 5.

Dynamic pressure Pa = Ά. p. w? (Pa), where p is the air density (kg / m ³ ), w is the air velocity (m / s). In our case, only the velocity component of the air flow perpendicular to the area of the door opening 4 is applied, which is determined by calculating W4 = W2. cos a. Then dynamic pressure Pa = Ά. p. (w2 cos a) ² (Pa) must be equal to the required static air overpressure P _s (Pa), for example 10 (Pa), in order to prevent air flow through the door out of the protected escape route and the associated loss of the required overpressure.

The application shown in the plan view in Fig. 2 is an example of an embodiment where the device 5 is installed in a vertical position on both sides of the door 1. The evaluation and setting of operating parameters takes place in the control unit similarly to the previous example in Fig. 1.

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The application shown in the plan view in Fig. 3 is an example of an embodiment where the device 5 is installed in a vertical position along one of the sides of the door L. The evaluation and setting of operating parameters takes place in the control unit similarly to the previous example in Fig. 1.

The application shown in section in Fig. 4 is an example of an embodiment where the device 5 for generating a dynamic air stream 2 is installed in a horizontal position above the door L. The device 5 is provided with a control unit which is integrated in the operation controller of the dynamic direction and intensity control device 5. air flow 2. The control unit is connected to the differential pressure sensor 6, between the initial air pressure space 4 and the vacuum space 13, and further the control unit is connected to the door status sensor 1, which continuously monitors whether the door 1 is open, open or closed. closed. The control unit is provided with a data storage on which a software module is stored, which contains a program for calculating the angle and direction and intensity of the produced directed dynamic air stream 2 from the device 5. The resulting dynamic component 9 of air acting against static vacuum changes according to the pressure difference.

Industrial applicability

The method for preventing the loss of overpressure when opening a door and the system for carrying out this method according to the invention find application in the field of air conditioning, in particular in applications in the field of maintaining artificial overpressure, such as protected escape routes, overpressure research, medical, food or production premises.

Claims (10)

PATENT CLAIMS A method for preventing a loss of pressure difference when opening a door (1), in which the condition of the door (1) is continuously monitored, characterized in that an air barrier is formed on the side of the door (1) with overpressure in front of the opening door (1). from a directed dynamic air flow (2) which is maintained until the door (1) is closed. Method according to Claim 1, characterized in that the actual value of the pressure difference is measured, after which the intensity of the dynamic air flow (2) and / or the direction of the dynamic air flow (2) changes according to the currently measured value of the pressure difference. Method according to claim 2, characterized in that the direction of the dynamic air flow (2) forms an angle (α) with the parallel planar surface of the door (1) in the range from 0 ° to 20 °. Method according to one of Claims 1 to 3, characterized in that the beginning of the air stream (2) is arranged horizontally above the door (1). Method according to one of Claims 1 to 3, characterized in that the beginning of the air stream (2) is arranged vertically along at least one side of the door (1). Method according to one of Claims 1 to 5, characterized in that the air for forming the air barrier is sucked in from the overpressure space (3) or from the initial pressure space (4). A system for carrying out the method according to any one of claims 1 to 6, comprising at least one device (5) for generating a directed dynamic air flow (2), and further at least one pressure difference sensor (6) between spaces (3, 4) connected by a door (1), characterized in that the device (5) is located on the side of the door (1) with a prevailing overpressure, that the device (5) is arranged -5 CZ 2019 - 423 A3 horizontally above the door (1), or vertically at at least one side of the door (1), for propagating a dynamic flow (2) of air from the device (5) towards the opposite end of the door (1), further that it is connected to at least one control unit for controlling the operation of the system connected to the differential pressure sensor (6), and further to that at least one door status sensor (1) is connected to the control unit. System according to claim 7, characterized in that the control unit is provided with at least one data storage for storing the control software module of the device operation (5), the control unit being connected to the operation and air output controller of the device (5), or operation and air output of the device (5) part of the control unit. System according to Claim 7 or 8, characterized in that the air intake device (5) is connected to the overpressure space (3) and / or to the initial pressure space (4). System according to one of Claims 7 to 9, characterized in that the device (5) is formed by an air curtain.