RU62918U1 - ELECTRIC DRIVING CRANE SAFETY SYSTEM - Google Patents

Abstract

The utility model relates to the field of hoisting and transport engineering and can be used in control systems and protection of hoisting machines with electric drive. The safety system of an electric hoisting crane contains a digital computing unit 1, the outputs of peripheral devices for registering crane parameters are connected to the information inputs of the multiplex data exchange channel, and the crane parameters recorder 3 with a real-time timer, visual indication unit 4, warning signaling unit 5 are connected to the outputs and an executive unit 6, and an external storage device 2, connected to the digital computing unit with a two-way data exchange channel. The system is equipped with meters 8 ₁ ... 8 _n parameters of the supply voltage of the crane electrical equipment, the outputs of which are connected by a multiplex communication channel to the additional information inputs of the digital computing unit and to the additional inputs of the crane parameters recorder and visual indication unit. The digital computing unit is suitable for comparing the measured voltage with acceptable parameters of the supply voltage, generating a signal to prohibit all movements of the crane when the parameters of the supply voltage deviate beyond the acceptable level for the crane control system, generating a signal to disable certain types of movements of the crane when the parameters of the supply voltage deviate outside acceptable level for crane drives and the formation of warning light and sound signals when the steam deviates Ameter of supply voltage is outside the acceptable level. Achievable technical result is expressed in increasing the reliability of the crane. 1 s.p. f-ly, 1 ill.

Description

The utility model relates to the field of hoisting and transport engineering and can be used in control systems and protection of hoisting machines.

According to the requirements of normative documentation, hoisting cranes are equipped with various types of safety devices and devices: working movement limiters, load capacity or load torque limiters, coordinate protection devices, devices for protection against falling loads and booms at electric cranes in case of breakage of any of the three phases of the power supply network, by blocking the operation of the corresponding mechanisms of the lifting machine, in accordance with the requirements of the rules of PB 10-382-00, etc.

Known crane safety systems containing a digital computing unit, to the information inputs of which are connected peripheral devices for recording crane parameters with a multiplex data exchange channel, and to the outputs are a crane parameter recorder with a real-time timer, a visual indication unit, a warning signaling unit and an executive unit, and external storage device connected to the digital computing unit with a two-way data exchange channel (see, for example, RF patent for floor znuyu model №38747, V66S 23/90, 10.07.2004 - prototype). The system according to RF patent No. 38747 was used in the ONK-160B integrated safety device (Load limiter of the ONK-160B tower crane. Operation manual. LGFI.408844.025-01RE, OJSC Arzamassky Instrument-Making Plant, pp. 1-19, 48-49) . The ONK-160B device provides protection of a tower crane from overloads and overturning when lifting a load, protection of working equipment from damage when working in cramped conditions

(coordinate protection), displaying information about the actual mass of the load lifted, the maximum load capacity, the degree of loading of the crane, the size of the departure, the height of the hook, the position of the crane on the way and wind speed. The crane parameter recorder integrated in this device provides recording and long-term storage of information about crane operating parameters, values and dates of overloads, and also about the crane loading level during the entire life of the limiter. However, the known security system does not exclude the possibility of disconnecting certain types of drives, such as a turning drive and a crane movement drive due to short-term voltage surges, which in itself can lead to an emergency due to load buildup.

Today, there are a number of instruments that measure the supply voltage in three phases, for example, EL-13 (CJSC MEANDR, St. Petersburg); UZOF-3M (CJSC ITC KROS, Ivanteevka, Moscow Region); "RKF-1" (OJSC "Eltor", Tver). These devices are used in electric hoisting cranes, but they have the following disadvantages:

1. The inability to control the parameters of the supply voltage (U _pit ) for relay automation of the crane, since the listed devices only protect the motors from overturning. This is due to the fact that there are a number of conflicting requirements for the supply voltage level for certain types of electrical equipment of a hoisting crane. For electric motors, phase imbalance up to 0.7U _{n is} allowed, where U _n is the nominal voltage, and a symmetrical voltage drop is up to 0.5U _n , and for relay automation, the permissible supply voltage range is 0.9U _n <U _pit <1.1U _n );

2. It is possible that certain types of drives can be disconnected, such as a rotation drive, a crane movement drive due to short-term voltage drops due to the fact that the listed devices cannot determine specifically in which phase the skew occurs. This causes all brake-activated drives to trip, including

rotation and movement drives of the crane, which in itself can lead to an emergency due to load buildup;

3. The lack of registration of the supply voltage level for a more objective investigation of the causes of possible emergency situations, since when the crane driver or the maintenance personnel of the above devices block the operation by interrupting the executive contacts and then removing such a lock, it is impossible to objectively determine the cause of the accident with the electric crane.

For example, on a KB-408.21 crane manufactured by the Nyazepetrovsk crane building plant using the phase monitoring relay EL-13, the following is monitored:

1. The phase imbalance of the supply voltage to the power motors up to 0.7U _n (i.e., it is allowed to reduce the voltage in a separate phase to 154V at a nominal voltage of 220V in other phases);

2. Symmetrical voltage reduction between phases to 0.5U _n (ie, it is allowed to reduce the linear voltage simultaneously between three phases to 190V).

However, for relay automation controlling power motors on the KB-408.21 crane, a supply voltage of 0.85U _{n is} allowed to be reduced (i.e., the supply voltage of relay automation coils should not be less than 323V).

Thus, the EL-13 phase monitoring relay cannot prevent the control circuit from operating at an unacceptable voltage level, which can lead to emergency situations. In addition, the EL-13 phase monitoring relay, when triggered, regardless of which of the three phases has a “voltage drop”, breaks its contact installed in the linear contactor circuit, which in turn turns off all crane drives, which can lead to unacceptable swinging of the load, especially when turning off the drive rotation.

The objective of this utility model is to create a crane safety system that provides differentiated

prohibition of the operation of various types of electrical equipment of the crane with unacceptable levels of supply voltage. An additional objective of this utility model is the elimination of emergency shutdowns of certain types of drives, such as a turning drive, a crane movement drive, due to short-term voltage surges. Another objective of this utility model is to register the supply voltage level for a more objective investigation of possible accidents, inform the crane driver about the supply voltage level and warn the crane driver about the deviation from the set supply voltage level.

Thus, the achieved technical result is expressed in increasing the reliability of the crane.

The solution of the problem and the achievement of the technical result is ensured by the fact that the safety system of the crane containing a digital computing unit, the outputs of peripheral devices for recording crane parameters are connected to the information inputs of the crane, and the crane parameters recorder with real-time timer is connected to the outputs, block visual indication, a warning block and an executive unit, and an external storage device connected to a digital The measuring unit is equipped with a two-way data exchange channel; it is equipped with meters of the supply voltage parameters of the crane electrical equipment, the outputs of which are connected by a multiplex communication channel to the additional information inputs of the digital computing unit and to the additional inputs of the crane parameter recorder and the visual indication unit, and the digital computing unit is adapted to compare the measured voltage with permissible parameters of the supply voltage, the formation of a signal to prohibit all movements of the crane When the supply voltage deviation parameters outside the permitted level for the crane control system, a signal for disabling individual species rejecting crane movements

parameters of the supply voltage outside the acceptable level for crane drives and the formation of warning light and sound signals when the deviation of the supply voltage parameters is outside the acceptable level.

Moreover, each meter of the supply voltage parameters of the crane electrical equipment is a series-connected divider, integrator and analog-to-digital converter, the output of which is the output of the meter.

The figure shows a functional diagram of the proposed safety system of a crane with electric drive.

The security system contains a digital computing unit 1, an external storage device 2, a crane parameter recorder 3 with a real-time timer integrated in it, a visual indication unit 4, an alarm signaling unit 5, an executive unit 6, peripheral devices 7 ₁ ... 7 _{m for} registering parameters tap and meters 8 ₁ ... 8 _n parameters of the supply voltage of the crane electrical equipment, for example, line voltage between phases, voltage between phases and neutral, etc.). Each meter 8 ₁ ... 8 _{n of the} supply voltage of the crane electrical equipment contains a series-connected divider 9, an integrator 10 and an analog-to-digital converter 11, the output of which is the output of the meter.

External storage device 2 is connected to the digital computing unit 1 by a two-way data exchange channel. The outputs of the digital computing unit are connected to a crane parameter recorder 3, a visual indication unit 4, a warning signal unit 5, and an executive unit 6.

The outputs of the peripheral devices 7 recording the parameters of the crane are connected by a multiplex data exchange channel to the inputs of the digital computing unit 1. The outputs of the meters 8 ₁ ... 8 _n parameters of the supply voltage of the electrical equipment of the crane are connected by a multiplex data channel to the additional information inputs

digital computing unit 1, as well as to additional inputs of the recorder 3 parameters of the crane and block 4 visual indication.

Peripheral devices 7 ₁ ... 7 _m recording the parameters of the crane are located in various areas of the crane and include analog sensors with analog-to-digital converters and digital sensors. Analog sensors measure the smoothly changing parameters of the crane and use sensitive elements with a linear and non-linear output signal to measure. Digital sensors measure the discrete parameters of the crane.

The system operates as follows.

During the operation of the crane, peripheral devices 7 ₁ ... 7 _m measure the parameters characterizing the loading of the crane and the position of its lifting equipment. Values of operating parameters of the crane are transmitted via a multiplex data exchange channel to a digital computing unit 1, which, using the program defined during the design of the safety device and pre-recorded in the external memory 2, compares the actual loading of the crane with the maximum permissible value, and also compares the actual position of the lifting equipment with the zone of its permissible positions, and depending on the results of comparisons gives a signal to the executive block 6 to allow or prohibit certain types of crane movements.

The parameters of the supply voltage U ₁ ... U _n are supplied through dividers 9 ₁ ... 9 _n (to reduce the signal level) and integrators 10 ₁ ... 10 _n (to determine the current voltage level) to analog-to-digital converters 11 ₁ . ..11 _n . Using a multiplex communication line, the signals from the outputs of the analog-to-digital converters 11 ₁ ... 11 _n are supplied to the digital computing unit 1, as well as to the crane parameter recorder 3 and the visual information block 4. In a digital computing unit, supply voltage levels are compared with predetermined levels in an external storage device.

For example, when using the proposed device on a KB-408.21 crane, based on the fact that the linear supply voltage between phases "A" and "C" (UAC) supplied to the control circuit must not be less than 323V, and the voltage on phase "B "must not be less than 154V, the indicated values of permissible supply voltages are entered into an external storage device. The calculator compares acceptable voltage levels with current values. If UAC <325V, all movements are switched off, since the crane control system cannot function normally. In the case when the voltage in phase "B" is less than 154V, only the hoist and outreach drives are switched off, and the crane movement and turn drives remain in operation, as they cannot lead to an emergency, for example, to a load drop. In addition, information about the insufficient voltage level of the supply network is supplied to the visual indication unit 4 and to the warning information unit 5. This makes it possible to quickly determine the reasons for stopping the crane drives and thereby reduce the downtime of the crane. Reporting cases of insufficient voltage levels also enhances the ability to investigate potential emergencies.

The claimed utility model can be manufactured industrially using modern components and technologies. To implement a digital computing unit, you can use the microprocessor MSP430F149 company "Texas Instruments" (USA) or other microprocessors of this type. Serial products of the Arzamas Instrument-Making Plant can be used as peripheral devices for registering crane parameters, for example, analogue motion sensors LGFI.401221.004, LGFI.401221.006, LGFI.401221.008 or new designs of digital sensors, in particular, digital pressure sensor LGFI.404176.013, and similar equipment of other instrument-making plants.

Claims (2)

1. The safety system of a crane with an electric drive, containing a digital computing unit, the information inputs of which are connected to the outputs of the peripheral devices for recording crane parameters, and the outputs are a crane parameters recorder with a real-time timer, a visual indication unit, a warning signaling unit, and an executive unit, and an external storage device connected to the digital computer unit with a two-way data exchange channel, characterized the fact that it is equipped with meters of the supply voltage parameters of the crane electrical equipment, the outputs of which are connected by a multiplex data exchange channel to the additional information inputs of the digital computing unit and to the additional inputs of the crane parameters recorder and the visual indication unit, and the digital computing unit is adapted to compare the measured voltage with valid parameters supply voltage, the formation of a signal on the prohibition of all movements of the crane when deviating the supply parameters conjugation beyond the permissible level for the crane control system, a signal for disabling individual species crane movements when the supply voltage deviation beyond the permissible level parameters for the crane drives, and generating a warning light and audible signal when a deviation of the supply voltage parameters outside the permitted level. 2. The system according to claim 1, characterized in that each meter of the parameters of the supply voltage of the electrical equipment of the crane contains a series-connected divider, integrator and analog-to-digital converter, the output of which is the output of the meter.