DE2319539A1 - COOLING DEVICE FOR AIR CONDITIONING SYSTEMS - Google Patents

Description

Priority: April 19, 1972 - ITALY

The invention relates to a cooling device, and more particularly a system in which means are provided to regulate the operation to prevent icing. The invention can be used in particular for air conditioning systems in motor vehicles.

The compressor of air conditioning systems of this type is usually driven by the vehicle engine via a clutch, for example via an electromagnetic clutch that can be engaged and disengaged by electrical control,

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ORiQiNAL INSPECTED

M 9489, - '. ■■

driven. To maintain the desired temperature of the evaporator of the system and especially to ■ prevent the outside temperature of the evaporator from reaching the icing point, which would cause ice to form in the gaps of the evaporator and thus a blockage of the cooling air ducts would result, whereby the efficiency the plant would be degraded is a heat sensitive one Element provided which causes the electromagnetic clutch to disengage when the measured Temperature is approaching the icing point.

The need to use an electromagnetic Coupling and a thermosensitive element in the plant leads to several disadvantages, the most important of which is the cost of manufacture and installation, the difficulty of calibrating the thermosensitive element, the tendency of the electromagnetic clutch to interfere and the difficulties caused by the repetitive sudden Engaging and disengaging the clutch of the compressor arise. The last-mentioned disadvantage is due to the inertia of the compressor and the power consumed by the compressor is, even if it is small, nevertheless considerable in terms of vehicle engine power.

The invention avoids these disadvantages by. Use of means to regulate the minimum temperature of the evaporator in that the supply of the refrigerant to a compressor which is constantly coupled to the vehicle engine is restricted instead of disconnecting the compressor, as has been the case up to now.

The cooling device according to the invention has a compressor, a condenser fed by the latter, one

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evaporator fed by the condenser and a device for connecting the outlet of the evaporator with the inlet of the compressor, which device is formed by a normally open valve arrangement, the is responsive to the pressure at its inlet port and moves to a position of restricted flow through it when the pressure at the mentioned inlet opening drops below a certain threshold value, that of a temperature on the evaporator close to the icing point is equivalent to.

There is one feature of embodiments of the invention in that when the refrigerant has passed through the evaporator it is in the form of a saturated vapor has so that a direct relationship between the temperature of the evaporator and the pressure of the refrigerant in this consists. In this way it is possible to adjust the pressure in the evaporator to regulate the temperature and the mode of operation to use the cooling device. It is relatively easy to measure this pressure with accuracy, on the contrary to temperature, which is difficult to measure accurately because it depends largely on the type of installation of the heat-sensitive Elements depends.

An embodiment of the invention is exemplified below described in more detail in connection with the accompanying drawings, namely show:

1 shows a schematic representation of a cooling device according to the invention and

FIG. 2 is a sectional view of a valve arrangement forming part of the device shown in FIG.

In Fig. 1, a compressor 10 of conventional type is shown,

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ORIGINAL INSPECTED

the refrigerant, which can be "Freon 12", for example, from an evaporator 12 via a line IU, a control valve 200 and _s a line 16 and sucks it under pressure via a line 18 and through a condenser 22, of which Output is connected to the evaporator 12 by a line 24. The valve 200 is also connected via a line 28 to a point 26 downstream of the compressor 10, which line 28 is connected to a control opening 225 of the valve 200.

The control valve 200 has a body 202 in which a first horizontal ^: (with respect to the orientation shown in FIG. 2) substantially cylindrical channel 203 is provided with an outlet port 201 connected to the compressor 10 and a second in the essentially cylindrical channel 204 with an inlet opening 206. The two channels 203 and 204 are connected to one another through an opening 208 with a wall 205, the upper edge of which forms a valve seat 1207.

The first channel 203 is provided with a radial bore 209 in the vicinity of the outlet opening 201, which bore communicates with a cylindrical chamber 210, the axis of which extends transversely to the axis of the channel 203. In the chamber 210 there is a closure piece 211 which is movable in such a way that it closes or closes the bore 209 a connection between the channel 203 and the chamber 210 can produce. A spring 212 is arranged so that it the locking piece 211 is loaded into the latter position. The axial position of the locking piece 211 and so that the opening and closing of the channel 203 is further influenced by the pressure in the chamber of a pressurized can,

309844 / CU 7 1

which can be a bellow-shaped box of a type known per se, inside which there is a vacuum. The pressurized can is held in its normal position by an internal spring (not shown) and contracts when the ambient pressure, i.e., the pressure within chamber 210, reaches a threshold. The top of the pressurized can is attached to a stopper 215 which closes the chamber 210 in a sealing manner.

The channel 204 is provided with a radial channel 216 which is in communication with a cylindrical chamber 217, which is substantially parallel to the cylindrical chamber 210. The channel 216 has a throttle point 216a, and In the chamber 217 a membrane 218 is fixed adjacent to the channel 215 which divides the chamber 217 into two parts divided. A first weak spring 219, which against the attached membrane 218 acts, pushes a closure piece with a flexible sealing ring made of elastomeric material against the valve seat .207. A plug 222 closes the upper end of the chamber 217 and is provided with an axial bore 223 is provided in which a piston 224 is slidable. the The axial position of the piston 224 depends on the pressure exerted against the upper side 224a and via a control port 2 25 is fed, which, as mentioned, via the line 28 to an opening of the compressor downstream connected is. At the same time, the position of the piston is also influenced by the force on its underside 224b is exerted by a compression spring 226 which is "arranged between the underside 224b and the membrane 218. The piston 224 can transmit its axial movement to the closure piece 220 via a shaft 227 which is attached to each its ends are seated in recesses 228 and 229 in the piston 224 and in the closure piece 220, respectively.

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The chambers 210 and 217 are in communication with one another via a line 230. The diameter of the bruise 216a -In the channel 216 is smaller than the diameter of the radial bore 209, so that when the latter is released the Pressure in chambers 210 and 217 becomes the same as that in channel 203. -

The spring 226 is sized for a pressure value which depends on the values of the parameters of the system, but in the described embodiment is approximately 19 atmospheres. When the pressure downstream of the compressor 10 exceeds the value to which the spring 226 is calibrated, the force exerted on the surface 224a of the piston 224 exceeds that exerted by the spring and the piston 224 moves to the passage 203, wherein it loads the shaft 227, this such that the locking piece 220 presses, which is therefore firmly pressed on denVentilsitz 207, whereby the freie.Verbindung is canceled, there was a νorher ₌ between the inlet port 206 and outlet port 201, and only a restricted connection remains via the bore 208 which is provided to prevent the compressor from sucking lubricating oil from its container. As soon as the valve plug 220 closes, the compressor 10 is substantially prevented from drawing in fluid so that the pressure at its outlet drops and the piston 224 can move upwards under the action of the spring 226. The valve closure piece 220 remains closed as a result of the pressure difference acting on it and as a result of the load from the spring 219.

However, if the pressure at the evaporator 12 increases due to a temperature increase, the pressure increase will be above the throttle point 216a and the channel 216 are transferred to the chamber 217, from which it receives access to the chamber 210 via the channel 230. When the pressure in the chamber 210 reaches the threshold of the

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Pressure cell 214 increases, for example, two atmospheres can be, the pressure cell contracts and allows, overcoming the action of the inner spring, that the spring 212 lifts the locking piece 211, whereby the Bore 209 is released} because the diameter of the bore 209 is larger than that of the throttle point 216a in the Channel 216 is, the pressure in the two chambers 210 and 217 falls as a result of the action of the compressor 10, which is constantly is in operation. The pressure difference at the closure piece 220 therefore lifts this from the valve seat 207 against the effect the spring 219 from, whereby the free connection between the inlet opening 206 and the outlet opening 201 is established again will. In this way, the compressor is brought back to its full capacity.

When the pressure in the chamber 210 falls below the calibration value of the pressure cell, it extends again and pushes against the closure piece 211, whereby the bore 209 is closed, and the pressure in the chamber 217 pushes this Closure piece 220 on the valve seat 207 back, whereby the direct connection between the openings 206 and 201 is interrupted.

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Claims ;

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Claims (2)

Claims Cooling device with a compressor, a condenser fed thereby, an evaporator supplied by the condenser and a device which connects the outlet of the evaporator to the inlet of the compressor, characterized in that said device is provided by a normally open valve arrangement; (200) is formed that. responsive to the pressure at its inlet port (206) and moves .in a position in which only a restricted flow takes place through them ^'1, when the pressure at the inlet opening (206) below a certain threshold drops of a temperature at the Evaporator (12) in the vicinity of the icing point corresponds. 2. Kühleinrichtung'nach claim 1, characterized in that that the valve arrangement has a valve body (202), 'the an inlet opening (206) which with the evaporator (12) is connected, and has a discharge port (201) which is connected to the compressor (10), wherein the inlet port and the outlet port (206), (201) with each other are connected via a valve to a valve seat (207) which is closed by a closure piece (220) can be, the position of which by a device (28, 225, 223, 217, 216) is controlled, which responds to the pressure in the inlet port (206) and serves to the . ■■ -.- ■ - 8 - .-3098 4 4/0471 To load the closure piece (220) against the valve seat (207) when the pressure in the inlet opening (206) is lower than the mentioned threshold. Cooling device according to claim 2, characterized in that that the pressure-sensitive device (28, 225, 223, 217, 216) has a control bore (209) which is connected to the outlet opening (206) of the valve arrangement (200), a valve closure piece (211) movable is to open or close the control bore (209) under the control of a pressure cell, which in a first chamber (210) is arranged, in which the pressure corresponds to the pressure in the evaporator through a first channel (230), which connects the first chamber (210) with a second chamber (217), in which the Mentioned main closure piece (220) is arranged, -and by a second channel (216), which the second chamber (217) connects to the inlet opening (206) of the valve arrangement (200), the opening of the control bore (209) a pressure reduction in the second chamber (217) results, whereby the opening of the main closure piece (2 * 20) enables and thereby the free connection between the inlet opening (206) and the outlet opening (201) again will be produced. For: FIAT SOCIETA PER AZIONI MnNTANWALTG Dft.- »». H. FINCKE, DIPI.-ING. K BOHS (MK.-IN &. 8th STASdEK • 309844/0471 M 948 Closure piece (220) against the valve seat (207) load if the pressure in the inlet opening (206) is lower than the mentioned threshold value. Cooling device according to Claim 2, characterized in that the pressure-sensitive device (28, 225, 223, 217, 216) has a control bore (209) which is connected to the outlet opening (206) of the valve arrangement (200), a valve closure piece ( 211) is movable to open or close the control bore (209) under the control of a pressure cell, which is arranged in ^: a first chamber (210) in which the pressure is equalized to the pressure in the evaporator through a first channel (230) which connects the first chamber (210) with a second chamber (217) in which the aforementioned main closure piece (220) is arranged, and through a second channel (216) which connects the second chamber (217) with the inlet opening ( 206) of the valve arrangement (200), the opening of the control bore (209) resulting in a pressure reduction in the second chamber (217), whereby the opening of the main closure piece (220) enables and thereby the free connection between the inlet opening ng (206) and the outlet port (201) is restored. ' For: -FIAT SOCIETA PER AZIONI UTaNTAMWXlTE OH-INO-RFINCKE ₁ DlPl ₁ -INe-KBOHe - 9 - 30984 4/0471