CN217917903U - Stall protection device for trackless rubber-tyred vehicle - Google Patents

Abstract

The utility model discloses a trackless rubber-tyred car stall protection device, include: a guide wheel; the arresting cable comprises an arresting part and a connecting part, wherein two ends of the arresting part are wound on guide wheels at corresponding ends to enable the arresting part to be supported to a preset height, and the connecting part is thrown out in the upward direction of the roadway; the energy absorber is connected with the connecting part on the side where the energy absorber is arranged; a buffer positioned at one side of the roadway and connected with a first connecting part of the two connecting parts; the actuator is positioned on the other side of the roadway and is provided with a rope winding mechanism, and the rope is connected with the second connecting part of the two connecting parts; and the tension sensor is connected in series with the second connecting part, the rope discharged by the actuator or between the rope discharged and the second connecting part, so that the actuator retracts the rope when the detected tension is smaller than a set value. Based on the utility model discloses a trackless rubber-tyred car stall protection device can carry out the automatic tensioning to the arrester wire.

Description

Stall protection device for trackless rubber-tyred vehicle

Technical Field

The utility model relates to a trackless rubber-tyred car stall protection device.

Background

Chinese patent document CN204488767U and priority document thereof propose a system for mounting a tail hook (also called a draw hook) on a trackless rubber-tyred vehicle for the first time, and a stall protection device for trackless rubber-tyred vehicle is mounted at a predetermined position of a roadway, for example, for protection in case of a running accident of the trackless rubber-tyred vehicle. The draw hook in the draw hook system is installed at the rear part of the frame through the fixed hinge support, for example, a hanging ring is installed on the upper side of the tail end of the draw hook, the hanging ring is pulled by the unlocking system, and when a sports car accident happens, the unlocking system is unlocked, and the draw hook falls. The trackless rubber-tyred vehicle stall protection device comprises a barrier cable (such as a steel wire rope) transversely arranged at a selected position of a roadway, the barrier cable is supported to a preset height, two ends of the barrier cable are respectively connected with an energy absorber, a falling drag hook can hook the barrier cable, and the energy absorbers act, so that the aim of forced deceleration is fulfilled.

As described above, in chinese patent document CN205223912U, the arrester wire needs to be supported at a predetermined height, and the arrester wire needs to have a certain tension, in that the arrester wire is placed transversely in a predetermined position of the roadway, for example, a trackless rubber-tyred vehicle usually runs centrally in the roadway, the position of the draw hook is approximately equal to the middle of the arrester wire, the middle suspension amount of the arrester wire is the largest part of the arrester wire, and if the middle suspension amount of the arrester wire is relatively large, the probability that the arrester wire is hooked by the draw hook which is lowered down is greatly reduced.

In view of this, in chinese patent document CN205223912U, the portion of the wire rope crossing the roadway is further supported by two guide wheels to have a certain height, which is beneficial to hooking the tail hook on the trackless rubber-tyred vehicle. And a spring type tensioning device, such as a spring guide post assembly, is further configured, so that on one hand, a steel wire rope part supported by the guide wheel is kept in a relatively stable suspended state through the tensioning of the tensioning device, and the blocking success rate is favorably improved. The inherent defect of this method is that, because the tensioning device adopts a spring guide post type tensioning device, the tensioning force is positively correlated with the stretching amount of the spring guide post, in other words, the tensioning force gradually decreases along with the reduction of the stretching amount. For the transverse arresting cable, when the trackless rubber-tyred vehicle normally passes through, the rubber-tyred vehicle rolls the arresting cable, so that the arresting cable generates plastic deformation, namely, the arresting cable gradually extends, so that the spring guide post retracts, the tensioning force is gradually weakened, the ground clearance of the middle part of the steel wire rope in a suspended state is inevitably reduced, finally, the steel wire rope is contacted with the ground of the roadway, manual tensioning is needed at the moment so as to enable the arresting cable to be in the suspended state again, otherwise, the arresting cable is in a quasi-failure state and cannot be in a good working state.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a can carry out the trackless rubber-tyred car stall protection device of automatic tensioning to the arresting cable.

The utility model discloses an in the embodiment, provide a trackless rubber-tyred car stall protection device, include:

the guide wheels are respectively arranged on two sides of the selected position of the roadway;

the stopping cable comprises a stopping part and connecting parts connected to two ends of the stopping part respectively, wherein two ends of the stopping part are wound on the guide wheels at the corresponding ends so that the stopping part is supported to a preset height, and the connecting parts are thrown out in the upward direction of the roadway;

the energy absorbers are respectively arranged on two sides of the roadway and connected with the connecting parts on the sides;

a buffer positioned at one side of the roadway and connected with a first connecting part of the two connecting parts;

the actuator is positioned on the other side of the roadway and is provided with a rope winding mechanism, and the rope is connected with the second connecting part of the two connecting parts; and

and the tension sensor is connected in series with the second connecting part, the rope discharged by the actuator or between the rope discharged and the second connecting part, so that the actuator retracts the rope when the detected tension is smaller than a set value.

Optionally, the tension sensor is connected in a manner that:

in a first mode, the actuator is provided with a control circuit board, and the tension sensor is connected to the control circuit board; the control circuit of the rope winding mechanism is controlled by or contained in the control circuit board;

in a second mode, the trackless rubber-tyred vehicle stall protection device is provided with a lower controller, and the tension sensor is connected to an input port of the lower controller; correspondingly, the control circuit of the rope winding mechanism is connected to the output port of the lower sensor;

in a third mode, the trackless rubber-tyred vehicle stall protection device is connected to an upper controller, and the tension sensor is connected to an input port of the upper controller; correspondingly, a control circuit of the rope winding mechanism is connected to an output port of the upper controller; or

In a fourth mode, the actuator is provided with a control circuit board, the stall protection device of the trackless rubber-tyred vehicle is connected with an upper controller, and the upper controller forms an upper computer of the control circuit board.

Optionally, the lower controller and the upper controller are provided with communication interfaces to access the mine monitoring system.

Optionally, the actuator is provided with a detection sensor for detecting the position of the tension sensor in order to avoid the tension sensor winding up a rope sheave of the rope winding mechanism.

Optionally, the detection sensor is configured to:

the first configuration is a photoelectric sensor and is arranged on a rack of the rope winding mechanism, and correspondingly, a jaw of the photoelectric sensor or emergent light vertically passes through a movement path of the tension sensor;

the second configuration is an ultrasonic sensor and is arranged on the frame of the rope winding mechanism, and correspondingly, the transmitting end of the ultrasonic sensor is vertically oriented to the motion path of the tension sensor;

the third configuration is a travel switch, the travel switch is configured on the rack of the rope winding mechanism, and correspondingly, the force arm driving end of the travel switch is positioned on the movement path of the tension sensor;

the fourth configuration is a grating ruler, is arranged in parallel with the motion path of the tension sensor and is positioned on one side of the motion path of the tension sensor; or

The fifth configuration is a rotary encoder, which is arranged at the shaft end of any shaft in the rope winding mechanism and the power machine thereof.

Optionally, the roping arrangement comprises:

a frame;

a sheave having a sheave shaft;

and the motor or the motor reducer assembly is provided with an output shaft connected with the rope wheel shaft.

Optionally, the sheave shaft is mounted on the frame by a bearing.

Optionally, an included angle between the axis of the guide wheel and the normal direction of the bottom surface of the roadway is 3 to 10 degrees, so that the connecting part is raised relative to the bottom surface of the roadway;

correspondingly, a supporting wheel for supporting the connecting part is further arranged to adjust the angle of the connecting part with the roadway bottom surface.

Alternatively, the connecting portion passes through the support wheel and then descends to connect with the buffer or the actuator, respectively.

Optionally, the buffer comprises:

one end of the cylinder is a seat end and is used for forming or mounting a tension spring seat;

the extension spring is accommodated in the cylinder, and one end of the extension spring is connected with the tension spring seat;

and the guide rod is guided in the cylinder, is connected with the other end of the extension spring and extends out of the other end of the cylinder, and the end part of the extending part of the guide rod is provided with a structure used for being connected with the corresponding connecting part.

The utility model discloses an in the embodiment, configuration tensile force sensor in trackless rubber-tyred car stall protection device for detect the tensile force of arresting cable, it should know, and the tensile force scope of the specific arresting cable that satisfies the arresting condition is definite, and under this condition, if current tensile force is less than the default, then send out the switching value, so that the executor action, the receipts rope through the wiring mechanism and realize carrying out the automatic tensioning to the arresting cable under the current state.

Drawings

Fig. 1 is a schematic top view of a stall protection device of a trackless rubber-tyred vehicle in an embodiment.

Fig. 2 is a view taken along direction a of fig. 1.

Fig. 3 is a view from direction B of fig. 1.

FIG. 4 is a schematic diagram of a main sectional structure of an actuator according to an embodiment.

Fig. 5 is a schematic top view of the actuator corresponding to fig. 4.

FIG. 6 is a diagram of a buffer structure.

Fig. 7 is an electrical schematic block diagram of a stall protection device of the trackless rubber-tyred vehicle in one embodiment.

Fig. 8 is an electrical schematic diagram of a stall protection device of the trackless rubber-tyred vehicle in an embodiment.

In the figure: 1. the energy absorber comprises a barrier cable, 2 parts of a guide wheel, 3 parts of a rope supporting wheel, 4 parts of a connecting rope, 5 parts of a tension sensor, 6 parts of an actuator, 7 parts of a buffer, 8 parts of an energy absorber rope and 9 parts of an energy absorber.

61. The machine comprises a machine shell, 62. An electric motor, 63. A machine base, 64. A speed reducer, 65. A support plate, 66. A transmission shaft, 67. A bearing and 68. A rope winding wheel.

71. Connecting hole 72, end plate 73, guide rod 74, guide ring 75, extension spring 76, cylinder 77, seat shell 78, hinge shaft hole 79 and ear plate 79.

t. roadway, w. roadway wall.

E. The mining explosion-proof and intrinsic safety type LED display screen is characterized by comprising a nearby power supply, a U mining explosion-proof and intrinsic safety type controller, an LED mining intrinsic safety type LED display screen, a SB mining intrinsic safety type button, an ST1 mining intrinsic safety type tension sensor, an ST2 infrared emitter and a JXH1 three-way junction box.

The device comprises an L-shaped live wire, an N-shaped zero line, a BA-shaped rectifier, a GL-shaped optical coupler, a PLC-shaped programmable logic controller, a KA1-shaped forward contact, a KA2-shaped overturning contact, a ZL-shaped rectifier and an M-shaped motor.

Detailed Description

It will be appreciated that in the case of a trackless rubber-tyred vehicle stall protection device, the rope coming out of the energy absorber 9, i.e. the energy absorber rope 8, is not under tension, so that in order to ensure that the arrester cord 1 is under tension, the arrester cord 1 needs to be tensioned by means of the buffer 7 and, for example, the tensioning device, the energy absorber rope 8 having sufficient margin to accommodate the change in the length of the arrester cord 1 caused by, for example, the trackless rubber-tyred vehicle passing under pressure against the arrester cord 1.

When the trackless rubber-tyred vehicle has a running accident, the trackless rubber-tyred vehicle provided with the tail hook releases the tail hook, if the tail hook catches the arresting cable 1, the energy absorber rope 8 is quickly tensioned, the energy absorber 9 starts to work, and in the process of releasing the longer energy absorber rope 8, the kinetic energy of the trackless rubber-tyred vehicle is gradually reduced, so that the stall protection of the trackless rubber-tyred vehicle is realized.

It should be noted that, in the case of a sports accident of the trackless rubber-tyred vehicle, that is, in the runaway state, the running direction of the trackless rubber-tyred vehicle is the down direction, and therefore, the basic orientation shown in fig. 1 is the left side in fig. 1 as the down direction side, and correspondingly, the right side in fig. 1 is the up direction side, and therefore, the horizontal arrow in fig. 1 indicates the running direction of the trackless rubber-tyred vehicle when the sports accident occurs.

Correspondingly, the arrangement position of the arrester cord 1 is arranged downward along the direction of the roadway t relative to the arrangement position of the buffer 9, and the rest parts of the trackless rubber-tyred vehicle stall protection device are positioned on two sides of the roadway t except the arresting part of the arrester cord 1.

Fig. 1 is a schematic top view structure diagram of a stall protection device of a trackless rubber-tyred vehicle in an embodiment, which shows main components of the stall protection device of the trackless rubber-tyred vehicle, including a arrester wire 1, a guide wheel 2, a rope supporting wheel 3, an actuator 6, a buffer 7, an energy absorber 9, and a rope, a rope clamp or other connecting structures for connecting main components.

The actuator 6 and the damper 7 are arranged in parallel with the damper 9 on the side, and at the same time they provide a direct effect on the pretensioning of the arrester cord 1, so that the energy absorber rope 8 can be in a relatively slack state for the energy absorber 9.

When the trackless rubber-tyred vehicle passes, the length change of the blocking part of the arrester wire 1, which is generated when the wheels press on the blocking part of the arrester wire 1, is adapted to the buffer 7.

Wherein, leading wheel 2 has two, respectively is equipped with one in the position both sides that tunnel t was selected, and this selected position is the sports car protection position of ore shang affirmation, belongs to the common knowledge in this field, and the no longer repeated description herein.

The guide wheel 2 is of a fixed pulley structure and is used for supporting the arresting cable 1 and adjusting the direction of the arresting cable 1 at two sides of the roadway.

It is obvious that the height of the rope groove of the guide wheel 2 determines the deployment height of the arrester cord 1, which is known to the person skilled in the art and will not be described in detail here.

The configuration of the guide wheel 2 preferably follows the structure and arrangement of the guide wheel 2 in chinese patent document CN 205223912U.

For the arresting cable 1, a steel wire rope is preferably used, and a rope material such as a steel strand or other rope materials similar to the steel wire rope, the steel strand and the like with toughness and enough tensile strength required by the arresting trackless rubber-tyred vehicle can be selected.

For the convenience of description, the arresting cable 1 is divided into a plurality of parts, namely, the arresting part arranged in the transverse direction of the roadway t and a connecting part for connecting the arresting cable 1 with the corresponding part of the trackless rubber-tyred vehicle stall protection device, wherein the connecting part and the arresting part are steel wire ropes in most embodiments and are not physically distinguished.

Based on the foregoing description, when the trackless rubber-tyred vehicle is blocked, the function of the blocking rope 1 on the trackless rubber-tyred vehicle is to pull up, so that the connection part is thrown from the guide wheel 2 on the corresponding side, thereby enabling the matching connection with the component on the corresponding side.

For blocking of a trackless rubber-tyred vehicle, for example, the energy absorber 9 plays a role in absorbing energy, and the energy absorber 9 belongs to a relatively typical mining product and is a necessary product for meeting coal mine safety regulations (2022). The device is usually fixedly installed at a preset position of a roadway t and used for realizing the blocking of vehicles such as mine cars, trackless rubber-tyred vehicles and the like which have car running accidents through energy consumption.

The line from the energy absorber 9 is typically a steel wire rope, i.e. the energy absorber line 8 illustrated in fig. 1, which is connected to the connection portion of the respective side by means of a wire rope clip or other connection.

The energy absorber rope 8 is normally not tensioned by pretensioning, but is in a relatively relaxed state, and tensioning of the arrester cord 1 requires additional components to achieve tensioning.

The additional components include the damper 7 and the actuator 6 in the embodiment of the present invention, and the actuator 6 is another type of tensioner or an improvement of the tensioner, compared to the prior art.

While known tensioning devices are generally purely mechanical tensioning devices, in the exemplary embodiment of the invention the actuator 6 is an electrical integrated device or comprises a mechanical part and an electrical part.

Wherein the mechanical part of the actuator 6 comprises a rope winding mechanism, the rope coming out of the rope winding mechanism is connected with the second of the two aforementioned connecting parts. The second connecting portion is used to distinguish a first connecting portion of the two connecting portions, which is used for connecting the buffer 7 with the blocking portion, without priority in order.

The electrical part of the actuator 6 is adapted to the tension sensor 5, wherein the tension sensor 5 is used to indirectly detect the tension of the arrester cable 1.

The sensor mechanical part of the tension sensor 5 is connected in series with the second connecting part and the rope discharged by the actuator 6 or between the rope discharged and the second connecting part, namely, the sensor mechanical part can be connected in series with any position of a rope assembly formed by the second connecting part and the rope discharged by the actuator 6, and the actuator is used for retracting the rope when the detected tension is smaller than a set value.

In addition, for the rope discharged from the actuator 6, if the tension sensor 5 is provided on the discharged rope, it is necessary to avoid the tension sensor 5 from being wound on the sheave of the actuator 6.

As a basic electrical connection, the foregoing description of the tension sensor 5 is embodied in a functional control, that is, when the tension detected by the tension sensor 5 is lower than a predetermined value, a switching value is sent out, and the actuator 6 acts to take up the rope until the tension reaches a preset value or a preset range. This is the switching value control, need not to pay creative work and can realize.

How the tension sensor 5 is connected to the electric part of the stall protection device of the trackless rubber-tyred vehicle is described below, which is referred to as a connection mode for short. The access method illustrated in the embodiments of the present invention is only used for exemplary illustration, and other access methods do not violate the concept of the present invention, and the same functions are realized, and still fall within the scope of the present invention.

The following factors are mainly considered with respect to the access mode:

first, in some embodiments, cost savings are considered, and there is a need for intensive operations in mines, such as configuring controllers, especially mining intrinsically safe controllers, which inevitably increase the cost of coal safety equipment.

Secondly, as a relative consideration, coal installation should be considered as a human-oriented one, and cost cannot be overemphasized.

Thirdly, as an additional option, in centralized control, it is desirable on some mine sites to be able to display the operating conditions of the field devices on an uphole monitor.

While a more optimal configuration is required for ideal coal installation, the situation on the mine varies and alternative embodiments are not necessarily compatible with the ideal configuration. It should be noted that coal installations are in development all the time, coal installations meeting early coal mine safety regulations do not necessarily meet the existing coal mine safety regulations, so that "ideal" also only exists in the current regulations, but the regulations themselves change very frequently.

The first mode of the access mode basically considers that a controller is omitted, an actuator does not need to be configured independently or externally connected with the controller, a control circuit board is configured for the actuator 6 at the moment, and a relay contact system such as a solid-state relay is adopted to realize the control of the main circuit of the actuator 6.

The main circuit of the actuator 6 may be a single-phase circuit or a three-phase circuit, and the distributed motor 62 may be a forward and reverse rotation motor or a unidirectional motor, preferably a forward and reverse rotation motor. The drive circuit of the corresponding main circuit, i.e. the motor 62, said control circuit board being connected to the control circuit of the main circuit.

Fig. 8 shows an electrical schematic diagram of the electrical components in one embodiment, which uses single phase power, and directly selects the on-mine power source for connection, briefly referred to as the proximity power source.

The control device shown in the figure is a PLC (programmable logic controller) shown in the figure, three PLCs are shown in the figure, only one PLC can be limited due to the fact that the number of points is small, and a plurality of PLCs are shown in the figure and are used for showing that the PLCs are used as upper computers and are not only used for controlling the stall protection device of the trackless rubber-tyred vehicle.

In fig. 8, 4 lines accessed by the optical coupler GL indicate an infrared signal, a reverse button, a forward button and an automatic button respectively, wherein the reverse button and the forward button are connected to the button switch for manually adjusting the tension degree of the arrester cord 1, and the arrester cord is used during equipment debugging or manual adjustment, and is controlled by a switch, which is not described herein again. The automatic button is used for starting automatic tensioning, and the automatic tensioning is detailed in context

The wiring that throws away alone on opto-coupler GL left side is the tensioning signal line for be connected with tensile force sensor 5, an I mouth of adaptation PLC.

Accordingly, for the motor M, the control circuit is connected to two O ports of the PLC for controlling the forward and reverse rotation of the motor M, which can be seen in fig. 8 as the forward contact KA1 and the reverse contact KA2.

As mentioned above, because the control mode is relatively simple, the tension sensor 5 is connected to the control circuit board, the control circuit board drives the control circuit to operate according to the setting of the solid-state relay, and the control circuit drives the main circuit to open and close the contactor.

In the second mode of the access mode, a traditional relay contact system is not adopted, the trackless rubber-tyred vehicle stall protection device is provided with a lower controller, because the control points are few, a singlechip (with the cost of about several yuan to dozens of yuan) with lower cost is selected when the actuator 6 is provided with an independent controller, basic operation is completed by the singlechip, for example, the tension sensor 5 is accessed to the input terminal of the singlechip, and one of the output terminals of the singlechip is connected with a control circuit of the main circuit through a relay.

In the third mode of the access mode, because the number of the control points is small, the corresponding control points can be accessed to an upper controller, for example, a PLC with 60 points can control a plurality of trackless rubber-tyred vehicle stall protection devices, and the third mode is not limited to one-to-one correspondence with the trackless rubber-tyred vehicle stall protection devices, so that the overall cost is saved.

Correspondingly, the trackless rubber-tyred vehicle stall protection device is connected to an upper controller, and the tension sensor 5 is connected to an input port of the upper controller; correspondingly, the control circuit of the rope winding mechanism is connected to the output port of the upper controller.

The fourth mode of the access mode is to access the upper controller when the actuator 6 is configured with the control circuit board, and this mode can be seen in the structure illustrated in fig. 7, in the drawing, the mining intrinsic safety and intrinsic safety controller U may be a PLC, and the actuator 6 may be controlled by the PLC or the control circuit board, or may be in division of work and cooperation in function control.

The host computer of the control circuit board is not shown in fig. 7 as a controller, and in some embodiments the host computer of the control circuit board may be a controller.

As previously mentioned, in some implementations, there may be higher requirements, and therefore, in some embodiments, the lower controller and the upper controller are equipped with communication interfaces to access the mine monitoring system.

The arrangement shown in fig. 7 is also provided with an infrared emitter which is mainly used to detect the position of the tension sensor 5 and avoid winding into the rope sheave of the rope winding mechanism, the infrared emitter acting as a photoelectric sensor, but other types of photoelectric sensors can be used.

There are more detection ways for the position detection of the tension sensor 5, in that it has a certain physical shape, and in the case of a certain position of the actuator 8 and the rope supporting wheel 3, the track of the tension sensor 5 following the rope outgoing movement of the actuator 8, for example, is basically determined, so that the detection sensor can be arranged at a predetermined position, and there are many options in the mechanical field, whether it is a mechanical contact type or a non-contact type.

Regarding the non-contact detection element comprising a photoelectric sensor, an ultrasonic sensor, a grating ruler and the like, the non-contact detection element is not easy to generate physical damage or abrasion due to mechanical contact, and has better use reliability.

The contact type detection element comprises a detection element which needs to be connected dynamically, such as a travel switch.

There is also a quasi-contact, i.e. rotary encoder, which often requires a shaft to be connected to a rotatable shaft, by sampling the amount of rotation of the rotating part to determine, for example, the amount of rope paid out.

As regards the detection sensor for detecting the tension sensor 5, it should be noted that in most applications it is not necessary to perform a full-stroke detection, but only a detection of reaching a safety-critical position, so that in most applications the position detection of the tension sensor 5 is limited to a detection of a safety-critical position in order to avoid the tension sensor 5 from winding up the rope winding wheel 68 with the rope coming out of the rope winding mechanism.

The configuration of the detection sensor on the stall protection device of the trackless rubber-tyred vehicle mainly has five basic configurations, and the extended configuration made by simple transformation performed by a person skilled in the art on the basis of the five basic configurations still falls into the protection range of the utility model if the concept of the utility model is not violated.

The first configuration is to use a non-contact photoelectric sensor, such as the aforementioned infrared sensor, and to configure the non-contact photoelectric sensor on the frame of the rope winding mechanism, such as the relatively immovable portion in fig. 5.

Accordingly, the jaws of the photoelectric sensor or the outgoing light beam pass perpendicularly on the movement path of the tension sensor 5.

The second configuration is also a contactless detection element, in particular an ultrasonic sensor, which is arranged on the frame of the roping arrangement, the emitting end of the ultrasonic sensor correspondingly facing perpendicularly to the path of movement of the tension sensor 5.

In the third configuration, a contact-type detection element such as a travel switch is adopted, the travel switch is provided with a mechanical arm, namely a force arm, the push rod of the travel switch is actuated by pushing the mechanical arm of the travel switch, the travel switch is configured on the frame of the rope winding mechanism, and correspondingly, the force arm driving end of the travel switch is positioned on the movement path of the tension sensor.

And in the fourth configuration, a non-contact detection grating ruler is adopted, and the grating ruler is arranged in parallel with the motion path of the tension sensor 5 and is positioned on one side of the motion path of the tension sensor 5.

And in the fifth configuration, a quasi-contact rotary encoder is adopted, and the rotary encoder is configured at the shaft end of any shaft in the rope winding mechanism and the power machine thereof.

In the structure illustrated in fig. 4 and 5, the roping mechanism comprises:

a housing including a case 61, a base 63, and a support plate 65 shown in fig. 4 and 5;

a sheave having a sheave shaft, which is indicated as a rope winding sheave 68 in fig. 4, and which winds a rope by rotating and, if having a forward and reverse rotation function, can take up or release the rope;

and the motor or the motor reducer assembly is provided with an output shaft connected with the rope wheel shaft.

As for the motor provided in the rope winding mechanism, the motor 62 as illustrated in fig. 4 is preferably a forward/reverse motor to pay out or take in the rope as needed.

The sheave shaft is mounted on the frame by means of bearings 67 in fig. 4 and 5, and the transmission shaft 66 visible in fig. 4 is arranged at a slightly larger distance from the reduction gear 64 for connection of the sheave shaft, and the transmission shaft 66 is arranged for connection, and the transmission shaft 66 is supported on the frame by means of a support plate 65. The support is obviously a dynamic support and the drive shaft 66 may be supported by suitable bearings.

As can be seen from fig. 2 and 3, the connecting part of the arrester wire 1 has a rising posture relative to the bottom surface of the tunnel t to facilitate tensioning, and in order to avoid generating additional supporting load, an included angle between the axis of the guide wheel 2 and the normal direction of the bottom surface of the tunnel t is 3 to 10 degrees, so that the connecting part has a rising posture relative to the bottom surface of the tunnel t.

Accordingly, a supporting wheel for supporting the connection portion is further provided to adjust the angle of the connection portion with the roadway floor, the supporting wheel can be seen in the rope supporting wheel 3 shown in fig. 2 and 3, which is a kind of fixed pulley, and the angle of the supporting portion can be changed in the condition of supporting the connection portion.

To facilitate tensioning, the connecting part is passed behind the supporting wheel and runs downwards to be connected to the damper 7 or the actuator 6, respectively.

Fig. 6 illustrates a structure of a buffer 7, and the buffer 7 is a modification of the spring guide post assembly as a whole, and the structure is embodied in that the buffer 7 includes:

the cylinder 76, which is shown as a seat end at the right end of the cylinder 76, is used to form or mount a tension spring seat, such as the tension spring seat shown in fig. 6, which is configured as a barrel having internal threads and the right end of the cylinder 76 having external threads, and is connected by threads, and a lug 79 is welded to the right end of the barrel for connecting a corresponding rope.

In some embodiments, the cylinder 76 itself forms the barrel, assuming the right end is sealed, and the sealed end is welded with lugs 79, as above.

The part of the buffer 7 providing the buffer is an extension spring 75, the extension spring 75 is accommodated in the cylinder 76, and one end of the extension spring 75 is connected with the tension spring seat, in fig. 6, the part for connecting the extension spring 76 with the tension spring seat is a fixed pin, and the hook of the extension spring 75 is hung on the fixed pin.

In fig. 6, the tension spring seat comprises said fixing pin, which, although fixed to the cylinder 76, in the functional positioning based on the tension spring 75, its fixed end connection must be connected by the tension spring seat.

The end of the tension spring 75 opposite to the fixed end is a floating end, and the floating end is connected to the guide rod 73 in the configuration illustrated in fig. 6, and provides a buffer by the floating of the guide rod 73.

Accordingly, the guide rod 73 is guided to the cylinder 76 and connected to the right end of the tension spring 75 in fig. 6, and the guide rod 73 protrudes from the other end of the cylinder 76, and the end of the protruding portion of the guide rod 73 has a structure for connecting with the corresponding connecting portion, such as the connecting hole 71 illustrated in fig. 6.

Claims (10)

1. The utility model provides a trackless rubber-tyred car stall protection device which characterized in that includes:

the guide wheels are respectively arranged on two sides of the position selected by the roadway;

the stopping cable comprises a stopping part and connecting parts connected to two ends of the stopping part respectively, wherein two ends of the stopping part are wound on the guide wheels at the corresponding ends so that the stopping part is supported to a preset height, and the connecting parts are thrown out in the upward direction of the roadway;

the energy absorbers are respectively arranged on two sides of the roadway and connected with the connecting parts on the sides;

a buffer positioned at one side of the roadway and connected with a first connecting part of the two connecting parts;

the actuator is positioned on the other side of the roadway and is provided with a rope winding mechanism, and the rope is connected with the second connecting part of the two connecting parts; and

and the tension sensor is connected in series with the second connecting part, the rope discharged by the actuator or between the rope discharged and the second connecting part, so that the actuator retracts the rope when the detected tension is smaller than a set value.

2. A trackless rubber-tyred vehicle stall protection device according to claim 1, characterized in that the access mode of tension sensor is:

in a first mode, the actuator is provided with a control circuit board, and the tension sensor is connected to the control circuit board; the control circuit of the rope winding mechanism is controlled by or contained in the control circuit board;

in a second mode, the trackless rubber-tyred vehicle stall protection device is provided with a lower controller, and the tension sensor is connected to an input port of the lower controller; correspondingly, the control circuit of the rope winding mechanism is connected to the output port of the lower sensor;

in a third mode, the trackless rubber-tyred vehicle stall protection device is connected to an upper controller, and the tension sensor is connected to an input port of the upper controller; correspondingly, a control circuit of the rope winding mechanism is connected to an output port of the upper controller; or

In a fourth mode, the actuator is provided with a control circuit board, the stall protection device of the trackless rubber-tyred vehicle is connected with an upper controller, and the upper controller forms an upper computer of the control circuit board.

3. The stall protection device for trackless rubber-tyred vehicles according to claim 2, wherein the lower controller and the upper controller are equipped with communication interfaces to access an on-mine monitoring system.

4. A trackless rubber-tyred vehicle stall protection apparatus according to claim 1, wherein the actuator is equipped with a detection sensor for detecting the position of the tension sensor to avoid the tension sensor from winding up the sheave of the rope winding mechanism.

5. The trackless rubber-tyred vehicle stall protection device of claim 4, wherein the detection sensor is configured to:

the first configuration is a photoelectric sensor and is arranged on a rack of the rope winding mechanism, and correspondingly, a jaw of the photoelectric sensor or emergent light vertically passes through a movement path of the tension sensor;

the second configuration is an ultrasonic sensor and is arranged on the frame of the rope winding mechanism, and correspondingly, the transmitting end of the ultrasonic sensor is vertically oriented to the motion path of the tension sensor;

the third configuration is a travel switch, the travel switch is configured on the rack of the rope winding mechanism, and correspondingly, the force arm driving end of the travel switch is positioned on the movement path of the tension sensor;

the fourth configuration is a grating ruler, is arranged in parallel with the motion path of the tension sensor and is positioned on one side of the motion path of the tension sensor; or

The fifth configuration is a rotary encoder, which is arranged at the shaft end of any shaft in the rope winding mechanism and the power machine thereof.

6. The trackless rubber-tyred vehicle stall protection device of claim 1, wherein the roping mechanism comprises:

a frame;

a sheave having a sheave shaft;

and the motor or the motor reducer assembly is provided with an output shaft connected with the rope wheel shaft.

7. A trackless rubber-tyred vehicle stall protection device according to claim 6, wherein said sheave is mounted on said frame by bearings.

8. The stall protection device for the trackless rubber-tyred vehicle according to claim 1, wherein an included angle between an axis of the guide wheel and a normal direction of a roadway bottom surface is 3 to 10 degrees, so that the connecting part is raised relative to the roadway bottom surface;

correspondingly, a supporting wheel for supporting the connecting part is further arranged to adjust the angle of the connecting part with the roadway bottom surface.

9. A trackless rubber-tyred vehicle stall protection apparatus as claimed in claim 8 wherein the link passes over the support wheels and then descends to connect with the buffer or actuator, respectively.

10. A trackless rubber-tyred vehicle stall protection device according to claim 1, wherein said bumper comprises:

one end of the cylinder is a seat end and is used for forming or mounting a tension spring seat;

the extension spring is accommodated in the cylinder, and one end of the extension spring is connected with the tension spring seat;

and the guide rod is guided in the cylinder, is connected with the other end of the extension spring and extends out of the other end of the cylinder, and the end part of the extending part of the guide rod is provided with a structure used for being connected with the corresponding connecting part.

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