SU1312334A1 - Room precision air-conditioning system - Google Patents

Abstract

The invention relates to ventilation technology and allows to extend the control range of a precision temperature field in the area of equipment. A vertical air duct 14 with a supercharger 15 is installed along the axis of symmetry of the room 1 and is communicated by the inlet 16 to the air Sf // / (L IPM .I

Description

A main channel (VC) 8, and an outlet 17 - with a distribution duct 9. Individual umbrellas 18 are installed above equipment 2 and connected to the air conditioner inlet 20. Temperature sensor 26 is located at VK 8 and is connected to the input of the control unit. The slotted holes are provided with adjustable elements. To spin the flow in the upper and lower zones of the layer 5 in opposite directions, the system is equipped with drive blowers 27, VK 8 is equipped with a filter 31, located. . . one

The invention relates to air conditioning and ventilation technology.

The aim of the invention is to expand the range of adjustment of the preventive 5: zone temperature field in the area where the equipment is located.

Figure 1 is a schematic diagram of a precision indoor air conditioning system; figure 2 - distribution duct, cross section.

Precision air conditioning system in the room 1, designed to accommodate high-precision monitoring equipment 2 to having double (outer and inner) walls 3 and 4 with an air gap 5 and a ceiling 6, about 5

20

7 air rope with the roof:

8, contains (FIG.) Distribution ducts 9 with slotted openings 10 (FIG. 2) located vertically in the perimeter space of room 1.

Underground exhaust duct 11 communicates with room I through exhaust openings 12 and 13 located along the perimeter of equipment 2 and walls 4.

Vertical duct 14 with a supercharger 15 is installed on. the axis of symmetry of the room 1 and reported by the input

16 with air channel 8 and exit

17- with distribution ducts 9.

Individual umbrellas 18 are installed above equipment 2 and with the aid of

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In front of the inlet 16 of the vertical air duct 14, the Visor 32, located at the point of connection to the AC 8 of the outlet 22 of the condenser and the exhaust duct 11, serves to more fully mix the air flow. The implementation of the outer wall 4 of a material having a greater heat capacity than the material of the inner wall 4 creates an effective damping of the amplitude of the heat wave caused by external influences. 6 h. apt. 2il.

five:

five

20

25

H

thirty

flexible pipelines 19 are connected to; air conditioner inlet 20 (not shown) i

In the vertical duct 14 is placed the heater 21.

The underground exhaust duct I1 and the outlet 22 of the air conditioner are jointly connected through the layer 5 to the air duct 8, and the slotted openings 10 of the distribution ducts 9 are equipped with adjustable elements that can be made in the form of elastic bands 23 (FIG. 2) parallel to each other. the length of the holes 10, and connected with their middle part of the pivot arms 24, fastened to the air ducts 9.

The first sensor 25 is located in the room 1 in the zone where the equipment is located. 2 and is connected to the first input of the control unit (not shown), the second temperature sensor 26 is located in the air duct 8 at the connection point of the exhaust duct 1I and the air conditioner outlet 22 to it, and the first and second outputs of the sub control unit. They are connected respectively to the heater 21 and the air conditioner.

Additional drive blowers 27 for swirling the flow in the upper and lower zones of the layer 5 in opposite directions can be located in the air gap 5 and at the outlet 22 of the air condioner, and the drives 28 and 29 of all blowers 15 and 27 are located outside room 1.

Lattices 210 can be installed in the exhaust holes 12 and 13

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adjustable louvers (not shown), and the air channel 8 can be equipped with a filter 31 located in front of the entrance 6 of the vertical duct 14.

Distribution, air ducts 9 can be placed symmetrically relative to each other, and the outer wall 3 can be made of a material having a greater heat capacity than the material of the inner wall 4.

In addition, the outer wall 4 of the room 1 can be equipped with a double wall.

20

25

An external guiding visor 32, 5 located at the point of connection to the air channel 8 of the outlet 22 of the air conditioner and the exhaust channel 11. Also, the exhaust channel 11 can be isolated in the area of the exhaust holes 12 from the air gap 5 using flexible overloads 33 made of elastic material, and the attachment of the levers 24 (Fig. 2) to the duct 9 can be carried out using, for example, a bracket 34 installed in the openings 10 of the duct 9.

The precision indoor air conditioning system works as follows.

The supply air is brought in the vertical air duct 14 to the required temperature, which regulates - using the temperature sensor 25 with the control unit connected to the heater 21, and is supplied through the distribution air ducts 9 to room 1. In this case air enters the room 1 through

The blinds enter the exhaust air duct 11, which reduces the temperature gradient of the lower part of the equipment 2. From the air duct 1I, air enters the air gap 5, where the air flows in the upper and lower zones of the interlayer 5 opposite sides using For example, low-power filling blowers 27 with providing uniform displacement of air currents and equalization of their temperature in the cross section of the layer 5.

Through the exit 22 of the air conditioner and the airless layer 5, two air streams enter the air channel 8, where they are mixed and, if necessary, cleaned of contamination and passing through the filter 31.

The temperature of the air mixture is controlled using a temperature sensor 26 and a control unit connected to the air conditioner.

Together with the temperature sensor 26, an air humidity sensor (not shown) can be connected to the control unit, and the ratio of external and recirculated air can be controlled by the air conditioner. From the air channel 8, the air enters again through the inlet 16 into the vertical duct 14, is heated in the preheater 21 to the required temperature, and through the distribution ducts 9 is supplied to the room 1.

To ensure a more complete air flow,

slit holes 10 are optimally non-0 from the exhaust channel 11 and from the exit of the circulating shape and direction of the air conditioner 22 on the outer wall of the inlet jets through each of the slit holes 10 with the greatest intensity of inflow in the zone of 45

equipment 2, which isolates it from the upper zone of room 1 with heat generated from natural convection, from where internal air is drawn through air conditioning inlet 20. –50 The main part of the incoming air flows around equipment 2 in the form of a symmetrically organized air flow and creates in the zone of its placement, an equally symmetric small gradient 55 is the temperature field.

From room 1, air through the exhaust holes 12 and 13 with regulator 3 is a double-sided guide visor 32. V

The implementation of the outer wall of a material having a greater heat capacity than the material of the inner wall creates an effective damping of the amplitude of the heat wave caused by external influences.

Formula of invention

1. Precision air conditioning system in a room designed to accommodate high-precision test equipment and has double walls with an air gap and overlap.

0

five

five

ABOUT

,

Blinds enter the exhaust underground channel 11, which reduces the temperature gradient in the lower part of the equipment 2. From the exhaust channel 1I, air enters the air gap 5, where the air flows in the upper and lower zones 5 of the layer 5 in opposite directions with using, for example, Low-Power Complementary Blowers 27, ensuring uniform displacement of air streams and equalization of their temperature in the cross section of interlayer 5.

Through the outlet 22 of the air conditioner and the air gap 5, two air streams enter the air duct 8, where they are mixed and, if necessary, cleaned of contamination when passing through the filter 31.

The temperature of the air mixture is controlled using a temperature sensor 26 and a control unit connected to the air conditioner.

In conjunction with the temperature sensor 26, an air humidity sensor (not shown) can be connected to the control unit, and the ratio of external and recirculated air can be controlled by an air conditioner. From the air channel 8, the air enters again through the inlet 16 into the vertical duct 14, is heated in the preheater 21 to the required temperature and is fed through the distribution ducts 9 into the room 1.

To ensure a more complete blend of air flow entering

0 from the exhaust duct 11 and from the outlet 22 of the air conditioner, on the outer wall

from the exhaust duct 11 and from the outlet 22 of the air conditioner, on the outer wall

3 there is a double-sided visor 32. V

The implementation of the outer wall of a material having a greater heat capacity than the material of the inner wall creates an effective damping of the amplitude of the heat wave caused by external influences.

Formula of invention

Claims (7)

1. Precision air conditioning system in the room, designed to accommodate high-precision test equipment and has double walls with air gap and overlap. forming an air channel with the roof, j containing distribution air ducts with slotted holes located vertically in the interior of the room, an underground outflow channel connected to the room through the holes of the equipment and walls, temperature sensor located in the area where the equipment is located and connected to the first input of the control unit, and an air conditioner, which means that, in order to extend the range of control of the precision temperature field in the area equipment placement, the system additionally contains a vertical air duct with a supercharger, installed along the axis of symmetry of the room and inlet with an air channel, and an outlet with distribution air ducts, individual umbrellas installed above the equipment and using flexible pipes connected to the air conditioner inlet, , a second temperature sensor connected to the second input of the control unit, and a heater placed in a vertical duct, underfloor exhaust duct and air conditioner outlet estno connected to an air layer through the channel and openings alkaline left distribution duct provided with adjustable elements, the second temperature sensor is disposed in the air passage at the connection thereto of the exhaust channel and exit kondshdionera, and first and second outputs councils block 46 Laziness connected respectively to the heater and air conditioner. 2. A pop-up system 1, characterized in that it is provided with additional driving superchargers, flow swirling in the upper and lower zones of the interlayer in opposite directions, and the drives of all superchargers are located outside the room. 3. System pop, 1, characterized in that the exhaust hole is -. The cabinets are equipped with grilles with adjustable louvers. 4. The system according to claim 1, which differs from the fact that the air duct is equipped with a filter located in front of the entrance of the vertical duct. 5. Pop. 1 system, differing by the fact that the distribution air ducts are displaced 1L1 symmetrically relative to each other. 6. A system characterized in that the adjustable elements of the slit openings of the distribution ducts are made in the form of elastic pents arranged parallel to each other along the length of the openings and connected to their middle part of the pivoting levers associated with the air ducts. 7. Pop. 1 system, differing in the fact that in the air gap on the outer wall of the room there is a double-sided visor located at the connection point to the air channel of the air conditioner outlet and the exhaust channel. mr 22 / About fpus.S Editor I.Nikolaychuk Compiled by M. Raschepkin Tehred L. Serdyukova Proofreader I.Nikolaychuk Order 1956/36 Circulation 660. Subscription VNIZHI State Committee of the USSR on affairs invented and discoveries 113035, Moscow, nd {-35, Raushsk nab., d.4 / 5 Production and printing company, Uzhgorod, Projecto st., 4