DEVICE FOR THE INTERMITTENT OPERATION OF THE COOLING FAN OF THREE-PHASE INDUCTION MOTORS, CONTROLLED BY THE TEMPERATURE OF THE STATOR WINDING

Abstract

The object of the present invention is to provide a device that allows the intermittent operation of the cooling fan, with a mechanism controlled by the stator temperature, to reduce whipping losses and improve the operating efficiency of three-phase induction motors for industrial use, such as those that operate pumps, compressors, conveyors, fans, welding machines and die cutters, among others.

Claims

1. A device for intermittent operation of the cooling fan of a three-phase electric induction motor comprising: A clutch mechanism between the fan (6) and the motor shaft consisting of two flanges, the first one, the shaft coupling flange (9), mounted on the motor shaft (8) configured to rotate next to the motor, and; The coupling flange (10), coupled to the fan (6) and an actuator fixed to the rear motor casing (2); A linear electric actuator (11) where the clutch mechanism engages and disengages the cooling fan (6) with the motor shaft (8); A temperature sensor (13) placed in the motor stator winding (7); A thermostat that responds to the temperature sensor (13) installed in the motor stator winding (7) and comes into contact with the linear actuator (11).

2. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 1, wherein the shaft coupling flange (9) also has metal balls (24) supported by springs incorporated into its surface.

3. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 1, wherein the fan coupling flange (10) has on its surface spherical cavities (26) in accordance with the balls (24) of the first flange.

4. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 1, wherein the control box (3) comprises a controller (14), a DC power supply (15), a temperature range selector (16), a data transmission and storage module (17), a data display module (18), a data transmission antenna (19) and four connectors (20), (21), (22), (23). These devices are electrically connected on a conventional electronic board.

5. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 4, wherein the connectors are derived from the group comprising the connector for the visual and audible alarm (20), the sensor connector (21), the external meter connectors (22) and the power supply connectors (23).

6. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 5, wherein the power supply connector (23) is coupled by mounting the fan mechanism casing (2) with the motor casing (2), wherein additionally the wired connection of the temperature sensor (13) installed in the motor stator winding (7) is connected to the thermostat and the data transmission and storage module (17).

7. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 4, wherein the data transmission and storage module (17) that is inside the control box (3), comprises a memory, a wireless and Ethernet systems for storing, obtaining and transmitting temperature data.

8. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 4, wherein the signaling module indicates the operating temperature range and the coupling or decoupling of the system.

9. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 4, wherein the temperature range selector selects a temperature according to the motor insulation system and sets the operating temperature range of the thermostat.

10. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 4, wherein the controller is connected to a monitoring center via wired and wireless communication lines that activate a visual or audible alarm, when the motor is exceeding the temperature range.

11. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 1, wherein the fan coupling mechanism comprises the coupling flange (10), the fan (16), the fan bearing (26), the linear actuator shaft (33), the linear actuator (11) and the linear actuator support (12) assembled together inside the casing (2).

12. A device for intermittent operation of the cooling fan of a three-phase electric motor according to claim 1, wherein the motor shaft coupling mechanism comprises the engagement of the metal balls (35), the metal balls (24) and the springs (36) together with the spring fitting (37) and the shaft coupling flange (9) assembled to the motor shaft (8).

13. The device for intermittent operation of the cooling fan of a three-phase electric induction motor according to claim 1, wherein: the temperature sensor is coupled to the motor stator winding; the thermostat and linear actuator are coupled to the motor casing; where the sensor measures the stator winding temperature and sends the signal to the thermostat, so that it in turn operates the linear actuator and the fan is coupled or disengaged.

14. The device for intermittent operation of the cooling fan of a three-phase electric induction motor according to claim 1, wherein: the temperature sensor is coupled to the motor stator winding; the controller is in the control box; and the linear actuator is arranged in the motor casing; where the sensor measures the stator winding temperature, the signal is sent to the controller and the linear actuator that couples or uncouples the fan is activated.

15. The device for intermittent operation of the cooling fan of a three-phase electric induction motor according to claim 1, wherein: the thermostat is arranged in the motor stator winding, the linear actuator that couples or disengages the ventilation is located in the motor casing.

16. The device for intermittent operation of the cooling fan of a three-phase electric induction motor according to claim 1, wherein: the temperature sensor is coupled to the motor stator winding; the thermostat and the linear actuator are arranged in the motor casing; the controller is in the control box; separated from the sensor, thermostat and linear actuator; wherein the stator winding sensor sends the signal to the thermostat and the actuator couples or uncouples the fan; In addition, the sensor sends a signal to the controller and the controller activates the alarms, sends information to the external connector and to the data transmission and storage module.

17. A method of measuring temperature for operating the cooling fan of the electric motor comprising: a. collecting information from the motor insulation system; b. measuring the stator winding temperature (7) permanently; c. according to the information of the motor insulation system, comparing the sensed temperature with the maximum and minimum permissible temperature range with the controller; d. coupling or de-coupling the cooling fan (6) from the motor shaft (8) through the clutch mechanism, where it remains uncoupled if the stator winding temperature (7) is below the maximum allowable temperature. If the stator winding temperature is higher than the maximum allowable temperature, the fan is coupled (6) and will remain in this state as long as the temperature is higher than the minimum permissible temperature.

18. A temperature measurement method for driving the electric motor cooling fan according to claim 13, comprising: a. measuring the temperature with the thermostat on the motor stator winding, which comes into contact with the linear actuator (11) and is connected to the display module through the controller; b. closing the actuator power circuit when the sensor registers a temperature greater than the upper limit of the established working range; c. coupling the fan: d. opening the circuit that feeds the linear actuator; e. switching off the fan when the sensor registers a temperature below the lower limit of the set temperature range.

Description

DESCRIPTION OF THE FIGURES

[0020] FIG. 1. Three-phase electric induction motor for industrial use.

[0021] FIG. 2. Side view of the three-phase electric induction motor for industrial use with coupling and re-position of the clutch mechanism.

[0022] FIG. 3. Side view of three-phase electric induction motor for industrial use

[0023] FIG. 4. Top view of the three-phase electric induction motor for industrial use with the control box.

[0024] FIG. 5. Enlarged view of the motor shaft coupling flange.

[0025] FIG. 6. Enlarged view of the fan coupling flange.

[0026] FIG. 7. Sectional view of the clutch mechanism.

[0027] FIG. 8. Exploded view of the fan side coupling mechanism.

[0028] FIG. 9. Exploded view of the motor side coupling mechanism.

[0029] FIG. 10. Intermittent operation of the motor cooling fan.

[0030] FIG. 11. Intermittent operation of the motor cooling fan where the temperature sensor is coupled to the motor stator winding and the thermostat together with the linear actuator to the motor casing.

[0031] FIG. 12. Intermittent operation of the motor cooling fan where the stator winding, thermostat and linear actuator are in the motor casing and the controller in a control box, separate from the sensor, thermostat and linear actuator.

[0032] FIG. 13. Intermittent operation of the motor cooling fan with a control box.

DETAIL DESCRIPTION OF THE INVENTION

[0033] In order to provide a detailed description of the invention, the device for the intermittent operation of the cooling fan of a three-phase electric induction motor is described, based on the figures provided.

[0034] FIG. 1 shows the three-phase electric induction motor for industrial use consisting of a motor (1), a fan casing (2) and a control box (3).

[0035] In FIG. 2, the coupling (4) and disengagement (5) position of the cooling fan (6) can be observed.

[0036] FIG. 3 shows the mechanical elements that allow the intermittent operation of the cooling fan. As can be seen, the motor shaft (8) and the cooling fan (6) are normally decoupled. These are coupled when the intermittent connection device of the cooling fan (6) is operated, by joining the shaft coupling flange (9) and the fan coupling flange (10). The fan coupling flange is assembled to the cooling fan (6), the linear actuator (11) and the actuator support (12). The intermittent coupling is operated according to the temperature measured by the temperature sensor (13) in the motor stator winding (7).

[0037] FIG. 4 shows the control box (3) with the electronic elements that allow the intermittent operation of the cooling fan. These elements, which are electrically connected to a conventional electronic board, allow collecting the temperature signal, processing the signal by comparison with the reference temperatures, and sending the operation signal to the mechanical elements of the device and the data storage and transmission. The electronic elements are: the controller (14), a DC power supply (15), a temperature range selector (16), a data transmission and storage module (17), a data display module (18), a data transmission antenna (19), the connector for the visual and audible alarm (20), the sensor connector (21), the external meter connectors (22) and the power supply connectors (23).

[0038] FIG. 5 shows the coupling flange of the motor shaft (9) with cylindrical geometric shape and some metal balls properly inserted (24) for assembly with the fan coupling shaft (10) shown in FIG. 6. The fan coupling flange (10) has geometric-shaped holes (25) identical to that of the balls (24) of the motor shaft coupling flange (9) (FIG. 5).

[0039] When the operating temperature reaches the maximum set temperature, the linear actuator (11) (FIG. 7) is engaged, pushing the flange that supports the cooling fan (10) axially towards the flange that is fixed to the shaft (9), producing the contact between the two flanges. In the first moments of the contact, friction is established for a short period of time, until the balls of the shaft flange (24) are introduced into the holes (25) of the flange that supports the cooling fan (10), the shaft being coupled with the cooling ventilation system.

[0040] FIG. 7 shows the linear actuator support (12) that externally supports and covers the linear actuator (11) up to a length of ¾ of the actuator length. The linear actuator is coupled to the inside of the fan bearing (26) and this in turn is fixed to the fan and the coupling flange.

[0041] The linear actuator support (12), shown in FIG. 8, is fixedly coupled at one end through a circular hole (27) located at the rear of the casing (2), ensuring that the mechanism is concentric. At the other end there is also a fastening means composed of four or more supports fixed by means of screws in the side holes (28) of the casing. This allows a symmetric distribution along the circumference of the linear actuator support (29).

[0042] The linear actuator (11) is assembled inside the linear actuator support and comprises three sections. The first section has a cylindrical shape (30), the second section (31) is the longest and has a hexagonal shape as shown in FIG. 8, while the third section (32) has a cylindrical shape with a bypass that engages with the axis of the linear actuator (33). This in turn is introduced into the bearing (34).

[0043] FIG. 9 shows the inside of the shaft flange (9) formed by the ball socket (35), the metal balls (24) and the springs (36) together with the spring socket (37). This flange is assembled to the motor shaft (8).

[0044] FIG. 10 illustrates the direction (201, 202) of the power supply and the signal of the device for intermittent operation of the linear actuator for intermittent coupling of the cooling fan of the three-phase induction motor controlled by the stator winding temperature, carried out by the thermostat by sensing the stator winding temperature constantly.

[0045] In the particular embodiment of FIG. 11, the temperature sensor is coupled to the motor stator winding and the thermostat together with the linear actuator to the motor casing. In this embodiment the sensor measures the stator winding temperature and sends the signal (202) to the thermostat so that it operates the linear actuator, arranged in the motor casing, and the fan is coupled or uncoupled.

[0046] In the embodiment of FIG. 12, the sensor is in the stator winding, the thermostat and the linear actuator in the motor casing and the controller in a control box, separate from the sensor, the thermostat and the linear actuator. In this embodiment, the motor stator winding sensor sends a signal (202) to the thermostat so that it in turn activates the linear actuator and the fan is coupled or uncoupled, this sensor also sends a signal (202) to the controller so that it activates the alarms, sends the information to the external connector and to the data transmission and storage module.

[0047] Additionally, in any of the above embodiments, the device may optionally comprise a separate controller that activates the visual and audible alarm, which sends sensed temperature information to the data transmission and storage module so that it in turn activates the data transmission antenna, and sends a signal (202) to the external connector so that through it a device measures the stator winding temperature and it is displayed through a motor temperature data display module, all optionally included in a control box (see FIG. 13).