FR2459428A1 - AIR CONDITIONER COMPRESSOR CONTROL CIRCUIT FOR VEHICLE - Google Patents

Abstract

VEHICLE AIR CONDITIONER COMPRESSOR CONTROL CIRCUIT. THE COMPRESSOR CONTROL CIRCUIT FOR AN AIR CONDITIONER IS DESIGNED, IN THE PRESENT INVENTION, FOR THE ELECTROMAGNETIC CLUTCH OF THE COMPRESSOR TO DISENGAGE ON A LEAK OF THE REFRIGERANT. A FUSE 8 IS CONNECTED TO A RELAY COIL 6B WHICH ACTIVATES A RELAY SWITCH 6A CONTROLLING AN ELECTROMAGNETIC CLUTCH SUPPLY CIRCUIT. A DETECTION SWITCH 7 IS ALSO PLACED IN SERIES WITH THE FUSE AND DETECTS ANY ABNORMAL SYSTEM CONDITIONS. WHEN THE DETECTION SWITCH CLOSES, THE FUSE BLOWS SO AS TO STOP THE OPERATION OF THE COMPRESSOR.

Description

Conditioner compressor control circuit

of air for vehicle.

  The present invention relates to an air conditioner compressor control circuit and relates, more particularly, to a compressor control circuit for a motor vehicle in which the electromagnetic clutch of the compressor is disengaged when the amount of gas

refrigerant decreases.

  An air conditioner for a motor vehicle

  includes a compressor driven by an engine through

  an electromagnetic clutch which is operatively disposed between the compressor drive shaft and a continuously driven pulley assembly;

by the engine.

  In accordance with the present invention, the Applicant has created an air conditioner compressor control circuit provided with a compressor, which circuit comprises: a source of electrical energy; a switch or relay contact set; the electromagnetic clutch of the compressor, this electromagnetic clutch being connected in series with said relay switch with respect to said source of electrical energy; a detection switch that closes when

  the detection of a refrigerant decrease in the condition-

  air neur; a fuse connected in series with the detector switch with respect to said source of electrical energy; and a relay coil to operate the relay switch,

  the relay coil is connected in parallel with the interrup-

  detector with respect to the source of electrical energy.

  An object of the present invention is therefore to provide an air conditioner compressor circuit in which an electromagnetic clutch disengages when

  the detection of a refrigerant decrease in the condition-

  air to prevent the compressor from being seized,

that is, blocked.

  The present invention will now be described with reference to: Figure 1 is a conventional compressor control circuit diagram of an air conditioner; and FIG. 2 is a compressor control circuit of

  air conditioner according to the present invention.

  Before describing the present invention, reference will first be made to FIG. 1 to explain a problem which has hitherto been encountered and which has been solved by the present invention.

  Referring to Figure 1, we see that we have

  presented a conventional air conditioner compressor control circuit for a motor vehicle, this circuit

  being provided with a source of electrical energy.

  main switch 2, such as an ignition switch, an air conditioner switch 4, a temperature control switch 3 and an electromagnetic clutch 5 are connected in series with respect to the source 1 of electrical energy. When all switches 2, 4 and 3 are closed, the electric current can pass through the electromagnetic clutch causing the engagement of the electromagnetic clutch and the transmission of the driving force from the motor to the compressor (not shown). The compressor then begins to compress the refrigerant in the thermal cycle. The condenser then condenses in a liquid form and is transferred to an evaporator present in the thermal cycle, thereby releasing fresh air into the vehicle cabin. When the temperature in

  the cabin falls below a predetermined value, the

  temperature control switch 3 opens by preventing the temperature from continuing to decrease, and then, when the temperature in the cabin increases again to a predetermined value, the temperature control switch 3 is closed again to cause a switchover to cooling mode operation. The setting of the temperature value can be adjusted variably by

  the temperature adjustment switch 3. It can be pre-

  fable that switch 4 air conditioner is kept open during the winter season in order to stop or

  to prevent the operation of the compressor so as to

  prime the load applied to the engine by the compressor.

  In the case of a compressor controlled by this prior art circuit, since the refrigerant circulates through a thermal cycle at the same time as the lubricant oil

  to prevent compressor seizure, leakage from the refrigerator

  manager, in the event that such a leak occurs, stop

  lubrication by causing the compressor to seize.

  With this prior art circuit, the compressor is able to operate even if the refrigerant has escaped with the lubricating oil, which results in insufficient lubrication of the compressor parts. This is so because the temperature control switch 3 remains closed when it detects an increase in temperature in the vehicle cabin as a result of a reduction in the cooling power of the conditioner.

  of air due to refrigerant leakage.

  The present invention, based on the finding of the problem mentioned above, is intended to provide an air conditioner compressor circuit in which a fuse is connected to a switch which detects an abnormal increase in the compressor temperature or an abnormal drop the refrigerant pressure, so that when such an abnormal condition is detected, the fuse

  cutting off the power supply of the electronic clutch

magnetic compressor.

  An embodiment of the present invention will now be described with reference to FIG.

  2, there is shown a compressor circuit. The same references

  Numerical references used in FIG. 1 are used herein to denote the equivalent elements. A relay is designated by the reference 6 and comprises a relay switch or set of contacts 10a and a coil 6b for controlling the start-up of the compressor, the relay switch 6a being

  connected in series with a temperature setting switch 3

  and one electromagnetic clutch 5. One of the relay coil 6b terminals is connected to the temperature setting switch 3 and the other terminal of the relay coil 6b is

  connected via a fuse 8 to ground. An inter

  main switch 2 and an air conditioner switch 4 are interposed between the source 1 of energy-electrical and the switch 3 of temperature control. In addition, a series circuit comprising a detection switch in the form of a temperature-sensitive switch 7 and a current limiting resistor 9 is connected in parallel to this relay coil 6b. The nominal value of the fuse 8 and the resistance value of the resistor 9 are chosen so that a normal current flowing through the relay coil 6b does not melt the fuse 8, but that fuse 8 melts under the action of a fuse 8. abnormal current flowing through it when switch 7

  temperature detection closes.

  We will now explain the operation of the circuit above. Operation is triggered by closing

  of the main switch 2, the switch 4 contion-

  Air neur and switch 3 temperature control.

  A current can then flow through these switches 2,4, 3, to the coil 6b of the relay and the fuse 8 causing the closing of the relay switch 6a. This allows the current to pass through the electromagnetic clutch 5 by putting

  running the compressor for a cooling operation.

  As long as the air conditioner is operating normally, the action

  compressor is controlled by the closing and opening

  temperature control switch 3 so that

  the ambient temperature is maintained within a predefined range

  completed. If the refrigerant leaks from the thermal cycle, the temperature of the compressor rises due to the heat produced by the friction. When the temperature reaches a

  predetermined value, the temperature increase of the compres-

  is detected by the temperature detection switch 7

  temperature. More precisely, when the temperature of the compressor has reached a predetermined level, the temperature detection switch 7 closes, which has the effect of closing the

  circuit-series comprising this switch 7 and the resistor 9.

  As a result, the fuse 8 melts by the heat produced by Joule effect by the current flowing through it. The current through the relay coil 6b is then interrupted, which causes the relay switch 6a to open and interrupts the power supply of the electromagnetic clutch 5. Consequently, the compressor stops working, thanks to to avoid damage to the compressor, damage

  which, without that, could happen.

  It should be noted that the detection switch 7 may be in the form of a pressure sensitive switch which closes upon detection of refrigerant leakage. With such a pressure sensitive switch, the same effect as that described above can be obtained for

  prevent jamming of the compressor.

  It can be seen from the foregoing description that,

  thanks to the present invention, it avoids seizing the compres-

  using a temperature sensing switch, a relay and a fuse, since the electromagnetic clutch is

  disengaged as a result of fusing the fuse when the

  temperature sensing switch detects compressor overheating or when a pressure switch detects

  a drop in the refrigerant pressure.

  It is further seen that the compressor circuit according to the present invention is very simple and can be manufactured

  without significant increase in manufacturing costs.

  It is understood that the foregoing description has not

  been given purely as an illustration and not as a limitation and that variants or modifications may be

  in the context of the present invention.

Claims (3)

  1. Compressor control circuit for a condition   air neur comprising a compressor, the aforementioned circuit being characterized in that it comprises a source (1) of electrical energy; a relay switch (6a); an electromagnetic clutch (5) of the compressor, said electromagnetic clutch being connected in series with said relay switch with respect to said source of electrical power; a detection switch (7) which closes when a refrigerant leak is detected in the air conditioner; a fuse (8) connected in series with said detection switch with respect to said source of electrical energy; and a relay coil (6b) for actuating said relay switch, said relay coil being connected in parallel with said detection switch with respect to said relay switch source of electrical energy.   2. Control circuit according to claim 1, characterized   characterized in that said detection switch is in the form of a pressure switch which   closes when a refrigerant pressure drop is detected.   3. Control circuit according to claim 1, characterized   characterized by the fact that said detection switch   present in the form of a temperature detection switch   erage that closes when an increase in compressor temperature.