RU2330806C1 - Device and method of lift cab suspenion system and lift cab suspension system assembly unit - Google Patents

Abstract

FIELD: transportation.

SUBSTANCE: invention proposes a device and a method to monitor the lift suspension system state and the lift cab suspension assembly unit made in compliance with the said device. The monitoring is based on measurement of an electric parameter, e.g. a suspended system resistance with ruling out the dependence upon the system temperature. The system resistance in primary state is calculated for the system monitoring temperature conditions and for those wherein the system exists in the monitoring process. The result is subtracted from the system measured cab suspension system resistance, the monitoring of which is being effected. To simplify the calculations and monitoring of the cab suspension resistance in primary state and the suspension system the monitoring of which is being effected can be converted into values of reference temperature.

EFFECT: higher quality of monitoring and safer lift operation.

19 cl, 4 dwg

Description

FIELD OF THE INVENTION

The present invention relates to elevator monitoring devices and, in particular, to a device that determines the degree of wear of a tensile system operating in suspension of an elevator car.

State of the art

Tensile suspension systems, such as coated steel tape or wire ropes, are often used in elevator devices to suspend an elevator car in a shaft. Over time, the natural bending of ropes or cables associated with the movement of the cab and counterweight leads to wear. With such wear, the cross section of the ropes or cables of the suspension system is reduced, which leads to a decrease in their strength. Therefore, it is advisable to regularly monitor the status of the cab suspension system to determine when to replace the device.

One way to control the condition of the rope is to monitor an electrical parameter, such as resistance, of the ropes of the cab suspension system. Reducing the cross-sectional area of the rope due to wear leads to an increase in rope resistance, which makes it possible to use the rope resistance measurement as a basis for determining the strength of a rope or its condition and set a resistance threshold at which the cab suspension system needs to be replaced.

However, temperature fluctuations in the elevator shaft will also affect the rope resistance. For example, the temperature at the top of the elevator shaft may be 10-20 ° C higher than the temperature at the bottom of the shaft. Since electrical resistance is also a function of temperature, changes in rope resistance due to temperature fluctuations can be so great that it makes it impossible to determine how large the change in resistance is associated with temperature fluctuations and what is the change in resistance associated with actual wear of the rope. In other words, changes in resistance due to temperature can mask the changes in resistance associated with wear, which makes it virtually impossible to correctly associate the resistance with the state of the rope.

Therefore, it is desirable to have a device for monitoring the suspension system of the elevator car, in which the influence of temperature fluctuations on the parameter being monitored is eliminated.

Disclosure of invention

SUBSTANCE: device for monitoring an elevator car suspension system is proposed, which comprises at least one temperature sensor located in the elevator shaft, an electric parameter measurement sensor of at least one part of the car suspension system, and a processor, which is a means of converting at least one measured electric parameter and electric the parameter of at least one part of the suspension system of the cabin in the initial state to values corresponding to the reference temperature, and and the influence of the temperature in the elevator shaft, measured by the specified at least one temperature sensor, the value corresponding to the measured electrical parameter is the measured value, and the value corresponding to the electrical parameter of the suspension system in the initial state is the reference value, and the processor is installed with the possibility the product of calculating the difference between the measured value and the reference value, comparing the magnitude of the corresponding difference with a given threshold and determining cab suspension system status. In this case, the processor can be a means of calculating the reference value by converting the electrical parameter of the specified at least one part of the suspension system in the initial state, while the reference temperature is equal to the temperature in the elevator shaft, measured by the specified at least one temperature sensor, and the measured value is equal to the measured electrical parameter. In another embodiment, the processor is a means of determining a temperature change of at least one of said sensors to a new temperature and recalculating the reference value for the new temperature.

In a further embodiment, the processor is a means of dividing the difference between the measured value and the reference value by a reference value to obtain a relative change amount, which is a value corresponding to the change, while the processor is a means of displaying wear of the suspension system of the cabin when the relative value of a predetermined threshold is exceeded. The value corresponding to the difference can be the difference between the measured value and the reference value, while the processor can be a means of displaying the wear of the suspension system of the cab when the difference of the set threshold is exceeded. In a particular case, the device may contain a group of temperature sensors, while the processor can be installed with the possibility of calculating a reference value for temperature readings received from a group of temperature sensors. The sensors in the group of temperature sensors can be located at the same distance from each other along the elevator shaft.

Also proposed is a node of the suspension system of the elevator car, comprising at least one temperature sensor, a sensor for measuring an electrical parameter of at least one part of the suspension system of the elevator car, and a processor that is a means of determining the temperature associated with at least one part of the suspension system of the elevator car , according to the at least one temperature sensor, by converting at least one measured electrical parameter and an electrical parameter of at least e of one part of the suspension system of the cabin in the initial state to the values corresponding to the reference temperature, and a means of taking into account the influence of temperature in the elevator shaft, the value corresponding to the measured electrical parameter is the measured value, and the value corresponding to the electrical parameter of the suspension system in the primary state is a reference value, wherein the processor is a means of calculating the difference between the measured value and the reference value and comparing the value with corresponding difference with a given threshold and means for determining the status of the suspension system of the cabin. The node may also further comprise a user interface, which is a means of displaying the wear of the suspension system of the elevator car when exceeding the difference of the set threshold. In a preferred embodiment, the processor is a means of calculating a reference value by converting the electrical parameter of the at least one part of the suspension system in the initial state, the reference temperature being equal to the temperature in the elevator shaft measured by the indicated at least one temperature sensor, and the measured value is equal to the measured electrical parameter. In another embodiment, the processor may be a means of dividing the difference between the measured value and the reference value by a reference value to obtain a relative change amount, which is a value corresponding to the change, and a means of displaying wear of the suspension system of the cabin when the relative value of the predetermined threshold is exceeded. In a particular case, the node may contain a group of temperature sensors located at the same distance from each other along the elevator shaft.

With another aspect of the invention, there is disclosed a method for monitoring an elevator car suspension system, in which the temperature associated with at least one part of the car suspension system is measured, a measured value of an electrical parameter of at least one part of the car suspension system is obtained, at least one measured electric parameter is converted and the electrical parameter of at least one part of the suspension system of the cabin in the initial state, take into account the influence of the measured temperature, and The value corresponding to the measured electrical parameter is the measured value, and the value corresponding to the electrical parameter of the suspension system in the initial state is the reference value, the difference between the measured value and the reference value is calculated, the corresponding difference is compared with a predetermined threshold, and the system state is determined hanging the cab. In the particular case, when the suspension system of the cabin contains several parts, the determination of temperature involves obtaining a number of temperature values, each temperature value being associated with different parts of the suspension system of the cabin, and the determination of the reference value includes converting the electrical parameter of each part of the suspension system in the initial state, taking into account the temperature this part and the summation of the converted electrical parameters of the parts of the suspension system in the initial state. Preferably, at the step of converting the electrical parameters, the reference value is determined by converting the electrical parameter of the at least one part of the cabin suspension system in the initial state, the reference temperature being equal to the measured temperature and the measured value equal to the measured electric parameter. In one embodiment, it is possible to additionally obtain a relative change in the value based on the reference value, while displaying the wear of the suspension system of the cabin when the value of the relative change exceeds a predetermined threshold. In the particular case, when determining the reference value, the electrical parameter of at least part of the suspension system of the cabin is determined under certain conditions for a set of temperatures. Certain conditions may constitute taking measurements before using the cab suspension system. In a particular case, the electrical parameter is resistance.

The present invention relates to a device and method for monitoring the status of a suspension system of an elevator car based on measuring an electrical parameter, such as the resistance of a suspension system. In one embodiment of the invention, the effect of temperature on the electrical parameter is compensated and the measured electrical parameter is isolated in such a way that it more accurately reflects the degree of wear of the suspension system, and not its temperature.

In another embodiment, a group of temperature sensors measures the temperature at various points along the elevator shaft. The system resistance in the initial state is calculated for the same temperature conditions in which the system is in the process of monitoring, and the result is subtracted from the measured resistance of the cabin suspension system, the state of which is monitored. The calculated difference reflects the change in resistance associated with the wear of the cab suspension system.

In another embodiment, a single temperature sensor is used to detect the effect of wear on the resistance of the cab suspension system. The use of a single temperature sensor in the device simplifies the calculation of resistance associated with wear. To further simplify calculations and monitoring, the resistance values of the suspension system in the initial state and the suspension system, which is monitored, can be converted to values for the reference temperature.

Brief Description of the Drawings

Figure 1 schematically shows an elevator device made in accordance with one embodiment of the invention.

2 is a flowchart illustrating a procedure in accordance with one embodiment of the invention.

3 is a flowchart illustrating a procedure in accordance with another embodiment of the invention.

4 is a flowchart illustrating a procedure in accordance with another embodiment of the invention.

The implementation of the invention

Figure 1 schematically shows the elevator device 100, made in accordance with one embodiment of the invention. The apparatus 100 comprises an elevator car 102 suspended by a tear-off system 104 for suspending a car, such as a tape rope in an elevator shaft. The suspension system 104 of the cabin is guided by one or more pulleys 106. The configuration of the pulleys 106 can be any known from the prior art and suitable for the elevator device 100 (for example, with a force of 1: 1, 1: 2, etc.).

Along the shaft of the elevator in the vertical direction are one or more temperature sensors 108. In one embodiment of the invention, the temperature sensors 108 are located at the same distance in positions h _i , vertically along the elevator shaft, where Δh is the distance between the sensors. The distance between the sensors 108 can be changed, however, at a constant distance, calculating the relationship between resistance and the state of the rope is somewhat simpler. In another embodiment, only one sensor 108 may be located in the elevator shaft 105 near the top of the shaft 105. These temperature sensors 108 are used to compensate for the electrical readings of the cabin suspension system 104.

One or more sensors 110 for measuring electrical parameters measure electrical parameters, such as resistance or conductivity, cabin suspension systems 104. Sensors 110 of electrical parameters can be located anywhere in the elevator device 100. Although it is assumed in the example below that sensors 110 of electrical parameters measure resistance, other electrical parameters can be measured and used in calculations without going beyond the scope of the present invention .

The processor 112 receives signals from temperature sensors 108 and resistance sensors 110. Based on the data from the temperature sensors 108, the processor 112 can normalize the data from the resistance sensors 110, thereby highlighting the changes associated with the wear of the cabin suspension system 104, and reducing or eliminating the effect of the temperature change on the resistance value. Through the user interface 113, information is provided about the device 100 in any form perceived by the consumer (for example, visual, sound, or both together).

If the device 100 contains only one temperature sensor 108, when processing in the processor 112, it is assumed that the temperature data from the sensor 108 represents the temperature throughout the elevator shaft or that the received data determines a predetermined temperature profile or its gradient. Such an assumption is, of course, approximate, but it gives acceptable results.

2 is a flowchart illustrating a method of normalizing resistance data in accordance with one embodiment of the invention. As is known from the prior art, the resistance of a metal rope varies mainly linearly depending on temperature, as well as on the geometry of the cross section of the rope. The relationship between the rope resistance and its cross-sectional area is expressed as R = ρL / A, where R is the total resistance of the rope (in Ohms), ρ is the total specific resistance of the rope material (in Ohm · m), L is the total length of the rope (in m) and A is the cross-sectional area of the rope (in m ² ).

In the embodiment of the invention shown in FIG. 2, it is assumed that a group of sensors 108 are placed along the shaft 105 of the elevator. Before any processing, the initial data is entered into the memory 114 associated with the processor 112 (block 200). These initial data include the resistance per unit length of the primary, unused rope and the change in this resistance depending on temperature, the number of sensors 108 in the elevator shaft 105, the distance h _i between all temperature sensors and the mounting configuration of the suspension system 104 of the cabin in the elevator shaft 105 . Although the resistance of the primary rope is ideally approximated by the expression R = ρL / A, in which ρ, L, and A are constant, changes in temperature in the elevator shaft 105 and changes in wear along the length of the cabin suspension system 104 will result in resistance readings along the length of the cabin suspension system 104 will also change. In this case, the total electrical resistance of a given rope in the cabin suspension system 104 is best approximated by the following equation:

where integration is carried out along the length L of the cabin suspension system 104.

Thus, the calculated total resistance of the primary rope under the same temperature conditions can be expressed as:

From Equation 2, it can be seen that the cross section A _{virgin of the} primary rope is assumed to be constant along the length of the cabin suspension system 104.

The data sent to the processor 112 at any given time is the temperature readings from the temperature sensors 108 and the current value of the rope resistance from the resistance sensors 110. The difference between the rope resistance R determined during the monitoring process and the primary rope resistance R _virgin can be expressed as:

It should be noted that equations 1 and 2 determine the total resistance under the same temperature conditions; thus, the influence of temperature on the readings of the resistance R in equation 3 is eliminated, and it reflects only the change in resistance due to wear of the rope.

It should also be noted that in equations 1 to 3, the temperature function T (z) along the elevator shaft is assumed to be continuous. In reality, however, only a finite number N of temperature sensors 108 will be located in the elevator shaft, which are preferably located at points h _i at equal distances Δh from each other, as shown in FIG. It should be noted that the temperature sensors 108 can also be spaced apart at unequal distances from each other, which is not beyond the scope of the present invention. Thus, the integral in equation 3 can be approximated by the sum, which results in the expression:

in which with _i is chosen in accordance with any of the known mathematical methods for approximating the integral, such as the Simpson formula or the trapezoid formula. As is known, with _i may be equal to 1 or 0.5 depending on the formula used and the value of i (for example, if i lies in the range from 1 to N, with _i may be equal to 0.5 if used for approximation by equation 4 trapezoid formulas). It should be noted that in the event of a different distance between the temperature sensors 108, one skilled in the art will know how to convert equation 4 to compensate for this difference.

The constant K in equation 4 can be introduced to take into account some excess length of the cabin suspension system compared with the height of the elevator shaft. Actual excess length may vary depending, for example, on the mounting configuration or elevator height. In most cases, the influence of the constant K is negligible, and it can be omitted, since the excess length is a small part of the total length of the cab suspension system. In one embodiment of the invention, K is 1 for a mounting configuration with one block, and K is 2 for a mounting configuration with two blocks. Of course, other K. values may also be used.

Thus, the processor 112 implementing the above equations receives the temperature values T (h _i ) from each of N temperature sensors (block 202), calculates the sum in accordance with equation 4 (block 204), and then subtracts the sum from the measured value of R to obtain a value ΔR (block 206). If desired, the measured resistance value R can be divided by the primary resistance value R _virgin to obtain a relative change in the resistance value due to a decrease in cross-sectional area (block 208). The change in resistance ΔR and / or the relative change can be compared with a threshold value for assessing the state of the cabin suspension system (block 210).

To simplify the calculations, the sensor system may contain only one temperature sensor 108 in the elevator shaft 105. In one embodiment, a temperature sensor 108 is located near the top of the elevator shaft 105. Since in this case only one temperature value from the sensor is considered, the calculation of resistance can be simplified, so that it turns out:

in which H is the length of the elevator shaft, L is the length of the cabin suspension system 104, and T (N) is the measured temperature in the elevator shaft. Compared to equation 4, the value of H in equation 5 can be considered as the corresponding (NI) dh, and L can be considered as the corresponding KN. If Equation 5 is used to monitor the status of the cab suspension system, the resistance values R _{virgin of the} primary system at different temperatures T (H) can be stored in the form of a code table, so that processor 112 can refer to the true value of R _virgin to subtract it from readings of resistance R for a given temperature T (N).

To convert the measured value of the resistance R and the primary resistance R _virgin (T (H)) to the selected reference temperature, both the measured resistance R and the primary resistance R (T (H)) can be divided by the ratio ρ (Т _o ) / ρ ( T (H)), where T _o is the selected reference temperature. The reference temperature T _{o is} preferably chosen close to room temperature to facilitate obtaining the resistance value R ' _virgin (T _o ) of the cabin suspension system in the initial state used by the processor 112. Next, converting the R and R _virgin values to the corresponding values for a given reference temperature T _o , you can evaluate the status of the cab suspension system using one R _virgin value and one resistance threshold value, rather than different values for each temperature.

After dividing by the specified ratio, the resistance difference at the reference temperature T _o can be expressed as:

As can be seen from equation 6, the transformed resistance difference ΔR 'can be approximated by subtracting the primary resistance R' _virgin from the converted resistance R 'for the reference temperature.

Although equations 5 and 6 give some approximation, they are accurate enough to monitor the state of the rope, since they nevertheless reduce the effect of temperature on the recorded resistance value R to a sufficient degree to highlight changes in resistance due to changes in the cross section of the rope. In experimental tests using one embodiment of the present invention, the difference in the calculations using only one temperature sensor 108 and using several temperature sensors 108 was about 3%, which is an error that can be taken into account by the appropriate choice of equipment replacement criteria and which is quite acceptable with given the complexity of systems with multiple sensors.

Figure 3 and 4 presents alternative embodiments of the invention, which can be implemented in the case of using only one temperature sensor 108. In the embodiment shown in FIG. 3, the processor uses a code table containing all the rope resistance values for the primary rope as a function of temperature. The processor then receives temperature data T (H) from the temperature sensors 108 and resistance values R from the sensors 110 for measuring electrical parameters (block 302). In this embodiment, in the processor 112, the temperature T (H) is considered as if it were the temperature in the entire elevator shaft.

The processor 112 then selects a value for R _virgin based on the temperature values T (H) (block 304) and then subtracts R _virgin from the resistance value R to obtain ΔR (block 306). If desired, the resistance difference ΔR can be divided by the primary value of the resistance R _virgin to obtain a relative change in resistance due to wear of the suspension system of the cabin (block 308). ΔR or a relative change in the resistance value can then be compared with a threshold resistance value (block 310).

In the alternative embodiment of FIG. 4, the initial values stored in the memory of the device 100 include primary resistance at a reference temperature R _virgin (T _o ). In this embodiment, the processor 112 receives the initial value R _'virgin (T _o) (block 311). After obtaining the temperature value T (H) and the resistance value R (block 312), the processor 112 can convert the measured resistance value R to an equivalent measured resistance value R 'at the reference temperature T _o before making any evaluations (block 314). In this case, there is no need for a table of codes of the primary resistance values R ' _virgin (T _o ), since R' _virgin (T _o ) will always be the same for a given value of T _o . After converting the measured resistance value R ', the primary resistance value for the reference temperature R' _virgin (T _o ) is subtracted from the converted value R 'to obtain the converted resistance difference ΔR' (block 316). This converted resistance difference ΔR 'is then compared with a threshold value for assessing the status of the cabin suspension system (block 318).

In all the embodiments of the invention described above, changes in the measured temperature to new values can cause the converted resistance to be converted to the new temperature. In addition, although in the examples above the focus is on converting the primary resistance to account for the measured temperature in the elevator shaft, both the primary resistance and / or the measured resistance can only be converted if the primary and measured resistance are evaluated based on the same reference temperature .

By compensating for the effect of temperature changes on the electrical parameters that are being monitored, this invention ensures that the changes reflected by these electrical parameters are due to wear on the cab suspension system. Thus, the electrical parameters can be directly related to the state of the cab suspension system and can be used to monitor and evaluate the residual strength of the system. This allows, for example, to set a single threshold to indicate that the system needs to be replaced, regardless of any temperature changes in the elevator shaft.

It should be understood that in the practice of the invention, various changes may be made to the embodiment described herein. The following claims are intended to define the scope of the invention and thereby encompass the scope of the claims, method, device and their equivalents.

Claims (19)

1. The monitoring device of the suspension system of the elevator car, containing at least one temperature sensor located in the elevator shaft, a sensor of the measured electrical parameter of at least one part of the suspension system of the cabin, and a processor, which is a means of comparing at least one measured electrical parameter, which is measured value, and the electrical parameter of at least one part of the suspension system of the cabin in the initial state, which is the reference value, for the difference between the reference temperature that existed during the initial state of the cabin suspension system and the temperature obtained from the above at least one temperature sensor and means for calculating the difference between the measured value and the reference value, comparing the corresponding difference with a given threshold and determining the state cab suspension systems. 2. The device according to claim 1, characterized in that the processor is a means of calculating the reference value by converting the electrical parameter of the specified at least one part of the suspension system in the initial state, while the reference temperature is equal to the temperature in the elevator shaft, measured at least one temperature sensor, and the measured value is equal to the measured electrical parameter. 3. The device according to claim 1, characterized in that the processor is a means of determining the temperature change of at least one of the specified sensor to a new temperature and convert the reference value for the new temperature. 4. The device according to claim 1, characterized in that the processor is installed with the possibility of dividing the difference between the measured value and the reference value by the reference value to obtain a relative change amount, which is a value corresponding to the change, while the processor is a means of displaying the wear of the cab suspension system when the relative value of the specified threshold is exceeded. 5. The device according to claim 1, characterized in that the value corresponding to the difference is the difference between the measured value and the reference value, while the processor is a means of displaying the wear of the suspension system of the cabin when the difference exceeds the set threshold. 6. The device according to claim 1, characterized in that it contains a group of temperature sensors, while the processor is installed with the possibility of calculating a reference value for temperature readings received from a group of temperature sensors. 7. The device according to claim 6, characterized in that the sensors in the group of temperature sensors are located at the same distance from each other along the elevator shaft. 8. The node of the suspension system of the elevator car, containing at least one temperature sensor located in the elevator shaft, a sensor of the measured electrical parameter of at least one part of the suspension system of the cabin, and a processor, which is a means of comparing at least one measured electrical parameter, which is measured value, and the electrical parameter of at least one part of the suspension system of the cabin in the initial state, which is the reference value, for the correspondence between the reference the actual temperature that existed during the initial state of the cabin suspension system, and the temperature obtained from the above at least one temperature sensor, and means for calculating the difference between the measured value and the reference value, comparing the corresponding difference with the given threshold and determining the state of the suspension system cabins. 9. The node of claim 8, characterized in that it further comprises a user interface, which is a means of displaying the wear of the suspension system of the elevator car when exceeding the difference of the set threshold. 10. The node of claim 8, characterized in that the processor is a means of calculating the reference value by converting the electrical parameter of the specified at least one part of the suspension system in the initial state, while the reference temperature is equal to the temperature in the elevator shaft, measured at least one temperature sensor, and the measured value is equal to the measured electrical parameter. 11. The node of claim 8, characterized in that the processor is a means of dividing the difference between the measured value and the reference value by the reference value to obtain a relative change amount, which is a value corresponding to the change, and a means of displaying wear of the suspension system of the cabin when the relative value is exceeded given threshold. 12. The node of claim 8, characterized in that it contains a group of temperature sensors located at the same distance from each other along the elevator shaft. 13. A method for monitoring an elevator car suspension system, according to which the temperature associated with at least one part of the car suspension system is measured, a measured value of an electrical parameter of at least one part of the car suspension system is obtained, at least one measured electric parameter and an electric parameter are converted at least one part of the suspension system of the cabin in the initial state, taking into account the influence of the measured temperature, and the value corresponding to the measured electric the electric parameter is the measured value, and the value corresponding to the electric parameter of the suspension system in the initial state is the reference value, the difference between the measured value and the reference value is calculated and the corresponding difference values are compared with a predetermined threshold and the state of the cab suspension system is determined. 14. The method according to item 13, wherein the cabin suspension system is divided into parts, the temperature values for each part are determined and the reference value is set by converting the electrical parameter of each part of the suspension system in the initial state, taking into account the temperature of this part and summing the converted electrical parameters of parts of the suspension system in the initial state. 15. The method according to item 13, wherein the conversion of electrical parameters determines the reference value by converting the electrical parameter of the specified at least one part of the suspension system of the cabin in the initial state, while the reference temperature is equal to the measured temperature, and the measured value is equal to the measured electrical parameter. 16. The method according to item 13, characterized in that it further obtains a relative change in the value based on the reference value, while displaying the wear of the suspension system of the cabin when the value of the relative change exceeds a predetermined threshold. 17. The method according to item 13, characterized in that when determining the reference value determine the electrical parameter of at least part of the suspension system of the cabin under certain conditions for a set of temperatures. 18. The method according to 17, characterized in that certain conditions are measurements taken before using the cab suspension system. 19. The method according to item 13, wherein the electrical parameter is resistance.

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