Brake controller and an elevator system

1 . A brake controller, comprising: a DC link for supplying power, said DC link including a positive DC link rail and a negative DC link rail; output terminals for coupling a magnetizing coil of an electromagnetic brake to the brake controller; and a current path established between said DC link and said output terminals for conducting DC link power to said magnetizing coil; herein the brake controller comprises two solid-state switches fitted into the current path, and wherein said solid state solid-state switches are configured to adjust output terminal voltage by modulating the DC link voltage. 2 . The brake controller according to claim 1 , wherein one of the solid-state switches is connected to the positive DC link rail and the other of the solid-state switches is connected to the negative DC link rail. 3 . The brake controller according to claim 1 , wherein the brake controller comprises: AC power input terminals; and a rectifier fitted between the DC link and the AC power input terminals. 4 . The brake controller according to claim 1 , herein the brake controller comprises a control circuit coupled to the control poles of the solid-state switches and configured to apply a modulation alternately to the solid-state switches. 5 . The brake controller according to claim 4 , wherein starting and stopping moment of the modulation of an individual solid-state switch is determined based on instantaneous temperature or change of the temperature of said solid-state switch. 6 . The brake controller according to claim 4 , wherein the control circuit is configured to control one of the solid-state switches to conduct continuously while the other solid state switch is modulating. 7 . The brake controller according to claim 3 , wherein the brake controller comprises: a safety input for receiving a safety signal; and a relay having a relay contact coupled in series with each of the current lines between AC power input terminals and the rectifier, wherein the safety input is coupled to the control coil of the relay. 8 . The brake controller according to claim 1 , wherein the brake controller comprises a DC link capacitor connected between positive and negative DC link rails. 9 . The brake controller according to claim 1 , wherein the brake controller comprises two current clamping diodes, one of the current clamping diodes being connected between the first output terminal and the negative DC link rail and the other of the current clamping diodes being connected between the second output terminal and the positive DC link rail. 10 . The brake controller according to claim 1 , wherein the solid state solid-state switches are of similar specification. 11 . The brake controller according to claim 1 , herein a length of the modulation period is substantially the same for both solid state switches substantially the same. 12 . The brake controller according to claim 1 , wherein the brake controller has two separate sets of output terminals for conducting DC link power to two separate magnetizing coils, wherein the brake controller comprises separate current paths established between the DC link and the first set of terminals and the DC link and the second set of terminals for conducting DC link power to the corresponding magnetizing coil, wherein the brake controller comprises two solid-state switches in both said current paths between the DC link and the corresponding output terminal, and wherein in both said current paths, both of the solid-state switches are configured to adjust corresponding output terminal voltage by modulating the DC link voltage. 13 . The brake controller according to claim 12 , wherein in both current paths, one of the solid-state switches is connected to the positive DC link rail and the other of the solid-state switches is connected to the negative DC link rail, wherein the control circuit is coupled to the control poles of the solid-state switches of both of the current paths, wherein the control circuit is configured to apply a modulation alternately to the solid-state switches of the first current path, and wherein the control circuit is configured to apply a modulation alternately to the solid-state switches of the second current path. 14 . An elevator system, comprising: an elevator car configured to move vertically inside an elevator shaft between stopping floors according to service requests, and requests; a hoisting machine for driving the elevator car; and one or more electromagnetic brakes for braking movement of the hoisting machine and/or the elevator car, wherein the elevator system comprises the brake controller according to claim 1 for controlling said one or more electromagnetic brakes. 15 . The brake controller according to claim 2 , wherein the brake controller comprises: AC power input terminals; and a rectifier fitted between the DC link and the AC power input terminals. 16 . The brake controller according to claim 2 , wherein the brake controller comprises a control circuit coupled to the control poles of the solid-state switches and configured to apply a modulation alternately to the solid-state switches. 17 . The brake controller according to claim 3 , wherein the brake controller comprises a control circuit coupled to the control poles of the solid-state switches and configured to apply a modulation alternately to the solid-state switches. 18 . The brake controller according to claim 5 , wherein the control circuit is configured to control one of the solid-state switches to conduct continuously while the other of the solid-state switches is modulating. 19 . The brake controller according to claim 4 , wherein the brake controller comprises: a safety input for receiving a safety signal; and a relay having a relay contact coupled in series with each of the current lines between AC power input terminals and the rectifier, wherein the safety input is coupled to the control coil of the relay. 20 . The brake controller according to claim 5 , wherein the brake controller comprises: a safety input for receiving a safety signal; and a relay having a relay contact coupled in series with each of the current lines between AC power input terminals and the rectifier, wherein the safety input is coupled to the control coil of the relay.