This invention relates generally to vehicle lifts and their controls, as well as to vehicle service systems having such vehicle lifts and controls. The invention is disclosed in conjunction with a unique electronic control which is simple and intuitive to operate, which may be stand alone or networked to other lift controls of the vehicle service system.
Hydraulic and electromechanical (screw) vehicle lifts for raising and lowering vehicles are well known. While the design and configuration of vehicle lifts vary, they all are used primarily for servicing vehicles. They must all have some type of control system to effect the raising and lowering function.
Prior art control systems for hydraulic lifts typically include an electric switch wired in series with the pump motor for raising the lift and a manually operated lowering valve for lowering the lift. Raising and lowering a vehicle into position requires a series of steps. Raising a vehicle with such a hydraulic lift requires depressing the electric switch to raise the vehicle, followed by operating the lowering valve to lower the lift to the locking mechanism. To lower a vehicle beyond the locking mechanism, such as to the ground, the first step is disengagement of the latches, which may be manually, electrically or pneumatically disengaged. The technician must first raise the lift off of the latches, and then either manually disengage the latches, or operate an electric switch or a pneumatic valve through a lever. The technician next operates the lowering valve while continuously operating the electric switch or pneumatic valve to hold the latches disengaged.
The vehicle lift and the area close by the lift, within which the technician moves and works on the vehicle is generally called the lift bay or service bay. To use the vehicle lift properly and safely, the technician needs accurate information regarding the safe operation and maintenance of the lift, such as for example vehicle lift points, operating conditions of the lift, maintenance and trouble shooting information. While working on a vehicle, a technician needs immediate access to current and accurate information regarding operating the lift and servicing the vehicle.
Typically, the information needed by a technician is not available at the lift bay. While the needed information is generally available as manuals or other printed form, such are frequently not kept in the service bay, if kept anywhere at all, and may be outdated. To obtain the information, the technician is thus usually required to leave the bay and locate the information. A technician may be unwilling to leave the bay to locate the information, since this adds another step to the technician's work schedule. A technician works more efficiently if everything needed to work on the vehicle is within the bay. Time spent by a technician away from the bay to obtain information, parts, process paper work, etc. detracts from the efficient performance of service on the vehicle.
Instruction on proper lift use is important for new technicians or new lifts. In such training situations, instruction may not occur at all if much effort is required to learn or teach the use of the lift or to locate the relevant instructional material. Instruction may be given by other technicians who may themselves not be aware of the proper operation of the lift, relying instead on their own understanding of operating the lift.
Proper lift maintenance is also important. Routine maintenance needs to be performed to keep a lift operating properly and safely. Although the need for preventative maintenance arises from the usage of the lift, information on preventative maintenance of lifts is not always readily available. Routine maintenance schedules may be kept independent of the lifts, and the technician does not know while he is in the lift bay whether routine maintenance needs to be performed. Maintenance information regarding repair or trouble shooting information is also typically not kept in the lift bay, resulting in limited or inefficient use of such important resource materials.
Although vehicle lifts define the service bay and are the focal point for servicing a vehicle, vehicle lifts themselves are considered secondary to other equipment used to service a vehicle. The view of the capabilities of a vehicle lift and its control has been limited to the raising and lowering functions, and has not extended to other functions. Thus, vehicle lifts and their controls have not been considered by those skilled in the art for providing access to information needed by the technician, or for collecting and transmitting information relative to operation of the lift of the servicing of the vehicle.
The present inventors have recognized that the overlooked vehicle lift and its control can meet the unrecognized needs for electronic delivery of information to and from the lift bay. The advent by the present invention of providing the ability to access, collect and transmit information by the vehicle lift control in addition to providing the lift functions, creates the new need to be able to revise the new non-lift functions of a lift control completely independent of the lift functions of the lift control. Because vehicle lifts are subject to third party certification, any changes to hardware or software which controls the lift functions, even if the changes only affect the non-lift functions, require recertification.
The accompanying drawings incorporated in and forming a part of the specification illustrate several aspects of the present invention, and together with the description serve to explain the principles of the invention. In the drawings:
Reference will now be made in detail to the present preferred embodiment of the invention, an example of which is illustrated in the accompanying drawings.
Referring now to the drawings in detail, wherein like numerals indicate the same elements throughout the views,
Although not shown, a spotting dish may be used with lift 2 to locate the vehicle in the appropriate position relative to columns 4.
On one of posts 4, lift 2 includes control assembly, generally indicated at 16. A slave control assembly 16a may be located on the other post 4, the operation of which will be described below.
Although the two lifts depicted in
Before describing control assembly 16 in detail, it is noted that although control assembly 16 is depicted as being attached to a post of a vehicle lift, it may be mounted separate from the lift which it controls, such as on wall or on a separate stand.
Turning now to
In the embodiment depicted, enclosure 28 includes first recessed area 30 having walls 30a extending inwardly toward a generally flat panel 30b which comprises display screen 32. Alternatively, display screen 32 could be omitted, as for slave control assembly 16a, and flat panel 30b could be formed integrally with enclosure 28 of the same material. Enclosure 28 carries user interface 31 comprising display screen 32 and key pad 34. Display screen 32 is disposed generally vertically at the rear thereof. In the embodiment depicted, display screen 32 is a LCD display, although any suitable display maybe used. By recessing display screen 32, glare is reduced.
Key pad 34 is disposed in first recessed area 30 below display screen 32. Key pad 34 is depicted as a generally flat panel which is tilted 30° up from horizontal, although any angle convenient to use may be used. Recessing key pad 34 aids in preventing accidental operation. As will be described in more detail below, key pad 34 comprises a keyboard with momentary contact switches underlying a flexible membrane which keeps contamination out of the switches. Any suitable user interface may be used, including for example, a touch screen display which functions as a switch to generate the desired signals upon touching the screen in the appropriate location. As will be described in detail below, in the embodiment depicted, key pad 34 comprises four keys formed as membrane switches. Although four keys are particularly suited for the particular embodiment depicted, it will be appreciated that more or less keys may be used. As used herein, key pad and keyboard include any user input device, including text input, touch screen input, etc.
Second recessed area 36 is disposed below first recessed area 30 having a generally vertical rear wall 38. Rear wall 38 includes opening 40 shaped complementarily to what ever component is to be disposed therein. In the embodiment depicted in
Control assembly 16 includes electrical disconnect switch 44 disposed along a side thereof. Switch 44 functions as an on/off switch which can be locked in the off position and as an emergency stop switch. When switch 44 is turned off, there is no power to control assembly 16 beyond switch 44 so that the lift cannot be operated and electrical outlet 42 is not powered. This allows a single lift bay to be shut down, such as for servicing, rather than shutting down any other devices on that same electrical circuit.
Enclosure 28 includes opening 46 along one side thereof, which permits the necessary electric and pneumatic connections to the interior of enclosure 28. As illustrated below, such electrical and pneumatic connections may be made to control assembly 16 in a variety of ways, some through opening 46 and some not through opening 46. Visible through opening 46 is back plate 48, described below.
Enclosure 28 includes access panel 50 which snaps into place as shown in access opening 52. Access opening 52 allows access to the fasteners which secure back plate 48 in place. In one embodiment of the present invention, particularly for use with a two post vehicle lift, the locking mechanism is located directly behind access panel 50 to allow access thereto for manual latch disengagement in the event of a power outage. If access through access opening 52 is not necessary, access opening 52 and access panel 50 may be omitted, having in place thereof an integrally formed panel.
Referring also to
In the embodiment depicted, back plate 48 carries all major components of the control except for assembly 66 and key pad 34, including carrying main circuit board 76, which carries first computer processor 104, electrical transformer 78, motor contactor 80 and audible signal sounder 82.
Referring now to
In the particular embodiment depicted in
Solenoid 88 is sufficient for use with two post light duty lifts, with one on each post. Each solenoid must be actuated. However, for other lift applications, such as the two or four post heavy duty lifts, the locking mechanism is actuated pneumatically. Disengagement of the pneumatic locking mechanism is accomplished through actuation of a solenoid operated pneumatic valve (not shown) which is pneumatically connected to each locking mechanism to disengage the latch. The pneumatic solenoid valve may be disposed within enclosure 28, or elsewhere on the lift, so long as the solenoid is electrically connected to the lift control. If the pneumatic solenoid valve is disposed within enclosure 28, pneumatic connections to connect to the pneumatic source and to connect the pneumatic solenoid valve to the latching/locking mechanisms must be provided. In such case, the pneumatic connections may be located internal or external to enclosure 28, such as extending from a side.
In case of power failure or other malfunction, in order to lower the vehicle beyond the discrete increments defined by locking mechanism 86, latch 90 must be manually disengaged. In the embodiment depicted in
Turning now to
Control 100 receives, generates and transmits a variety of condition signals which are indicative of various respective lift conditions related to the operation of the vehicle lift. As used herein, a signal includes an electric current or electromagnetic field used to convey data or effect an action, including for example, voltage, current, data imposed on a carrier signal and any more advanced signal forms, as well as the simple closing or opening of a switch of an electric circuit.
As illustrated in
Referring now to
In the depicted embodiment, each key 110, 112 and 116 performs more than one function. Which function is performed by each key 110, 112 and 116 depends on which mode of operation of control 100 has been selected or enabled by actuation of key 114. Key 114 is functional to cause control 100 to switch between the operating mode and the information mode, as described below in more detail.
Key 110, which includes up arrow indicia, is functional to cause the moveable lift engagement structure to raise, or to scroll up through a menu displayed on display screen 32 depending on the mode of operation of control 100. While in the operating mode, key 110 is actuated by depressing it, thereby transmitting a signal which enables the control logic of first computer processor 104 to generate a “raise” control signal in response thereto. The “raise” control signal energizes motor contactor coil 118 which closes the contacts of motor contactor 80, providing power to motor 12a thereby driving pump 12b and raising the moveable lift engagement structure. Vertical position sensors (not shown) could be provided and the user could be allowed to input through a user interface a selected height. Control 100 could then interrupt upward movement of the moveable lift engagement structure once the selected height is reached, despite continued actuation of key 110. It is noted vertical position sensors could also be used as a continuous position feedback system for individual control of the carriage or yoke.
Once the moveable lift engagement structure has been raised to a desired position, it may be lowered a bit so that latch 90 engages one of a plurality of steps formed between vertically aligned windows (not shown), resembling a ladder, which provides a positive mechanical lock preventing downward movement of the moveable lift engagement structure. Key 116, which includes “lower to lock” and “select” indicia, is functional to cause the moveable lift engagement structure to lower to the locks, or to select a menu option displayed on display screen 32, depending on the mode of control 100. While in the operating mode, actuation of key 116 transmits a signal which enables the control logic of computer processor 104 to generate a lower control signal in response thereto. The lower control signal opens lowering valve 120, which in the depicted embodiment is a solenoid operated valve, allowing the moveable lift engagement structure to lower. Since latch 90 is normally biased toward engagement, the moveable lift engagement structure can travel downwardly a short distance until latch 90 engages the next step.
Key 112, which includes down arrow indicia, is functional to cause the moveable lift engagement structure to lower, or to scroll down through a menu displayed on display screen 32, depending on the mode of control 100. While in the operating mode, key 112 is actuated by depressing it, thereby transmitting a signal which enables the control logic of first computer processor 104 to generate a signal to disengage latches 90 and to generate a “lower” control signal. In the depicted embodiment, latches 90 are held in a disengaged position by actuation of each respective solenoid 88. Alternatively, as described above, latches 90 may be operated pneumatically and disengaged by actuation of a solenoid valve providing pressure to pneumatic cylinders to hold latches 90 in a disengaged position. With latches 90 in the disengaged position, first computer processor 104 generates a “lower” control signal as described above, opening lowering valve 120, thereby lowering the moveable lift engagement structure.
It is noted that when the moveable lift engagement structure is to be lowered from a position at which latches 90 are in engagement with a step, the moveable lift engagement structure first needs to be raised to separate latches 90 from the step to relieve the force. In such a situation, the user will first actuate key 110 to raise the moveable lift engagement structure a distance sufficient to relieve the forces, and the actuate key 112 to lower the moveable lift engagement structure as far as desired. Alternatively, control 100 may be configured to do this automatically in response to actuation of key 112 when starting from the “lowered to locks” position.
Control 100 monitors a variety of lift conditions. As used herein, lift conditions include any condition related to the operation, control or maintenance condition of the lift. Control 100 may monitor some operation conditions through receipt of condition signals from sensors disposed to generate an output signal indicative of the operation condition associated with that sensor. In the depicted embodiment, optical overhead sensor 122 (see
The number and configuration of such sensors depend on the operation conditions monitored. For example, for inground lifts, a sensor could be provided to monitor the ground water level.
Other condition signals indicative of operation conditions may be monitored by control 100 without the use of sensors. For example, in the depicted embodiment, control 100 monitors the voltage in each driver circuit for the actuators (in the depicted embodiment, motor contactor coil 118, lowering valve 120, and latching mechanisms 86) as well as regulated and unregulated 24 VDC, and VCC 5 volt input.
Of course, control 100 may monitor any operation condition. For example, the following may be monitored: vertical position of moveable lift engagement structure, hydraulic and/or pneumatic pressure, force on arms 8, position of arms 8, position of the vehicle, points on the vehicle, out of level conditions, engagement/disengagement of latching mechanism 86, and wear on key components.
Some operation conditions may be monitored by control 100 only during certain operations, such as monitoring the toe guard sensor only when the lift is being lowered or the overhead sensor when the lift is being raised.
Computer processor 104 stores, in a non-volatile memory (such as an EEPROM), certain information regarding historical operation conditions, referred to herein as usage data, which can be used to track the performance of the lift. In the depicted embodiment, usage data stored by computer processor 104 includes the number of times motor contactor coil 118 has been energized (motor starts), the total time motor contactor coil 118 has been energized (motor on time), the number of times lowering valve 120 solenoid has been energized (lowering starts), the total time lowering valve 120 solenoid has been energized (lowering on time), the maximum length of time that lowering valve 120 solenoid has been energized (max lowering on time), the number of times that latch 90 (solenoid 88 or pneumatic valve solenoid) has been energized (latch starts), the total time latch 90 (solenoid 88 or pneumatic valve solenoid) has been energized (latch on time), the maximum length of time that latch 90 (solenoid 88 or pneumatic valve solenoid) has been energized (max latch on time), the number of times that overhead sensor 122 has been tripped (overhead cycles), and the number of times that toe guard sensor 126 has been tripped (lower sensor cycles).
Monitoring operation conditions involves access to information indicative of the condition being monitored and application of predetermined criteria to that information. Monitoring will result in a defined action if dictated by application of the predetermined criteria. Based on the application of predetermined criteria to the monitored operation conditions, the control logic of computer processor 104 will determine whether an operation fault condition exists, and if so, modify, including inhibit, the operation of the lift from that operation called for by user input, and in certain instances generate an operation fault indication signal which is transmitted to computer processor 106, which, in the depicted embodiment, enables display of operation fault data, i.e., data indicative of the operation fault condition. Additionally, such predetermined criteria can be applied to usage data.
Predetermined criteria applied by the control logic of computer processor 104 to operation conditions monitored through sensors, and the resultant actions by control 100 include, but are not limited to:
Predetermined criteria applied to operation conditions related to actuators, include, but are not limited to:
For each of the conditions related to the actuators, computer processor 104 will inhibit further movement of the moveable lift engagement structure, will enable the display of operation fault data indicative of the operation fault condition, and will flash LED indicator 128 (see
In monitoring the operation of motor 12c, latches 90 and lowering valve 120, computer processor 104 checks itself for faulty actuator drivers and faulty actuators (in the depicted embodiment, motor contactor coil 118, latch solenoid 88 (or pneumatic valve solenoid), and lowering valve 120 solenoid, although other actuators may be included) by checking the voltage at respective points in voltage divider circuits at each actuator driver output. When an actuator is supposed to be energized, computer processor 104 looks for at least a threshold voltage. If at least the threshold voltage is not present, then either the actuator driver is not delivering the required voltage to the actuator, or the actuator circuit is shorted. To determine whether an actuator is connected, computer processor 104 may also be configured to monitor current at the actuator or actuator driver. Actuator current data could be stored as usage data. When an actuator is not supposed to be energized, computer processor looks for no voltage at the actuator driver.
At power up, control 100 goes through a series of system checks, based on predetermined criteria, examining the status of all inputs and outputs of control 100 to make sure that they are in the correct state. In the depicted embodiment, this function is performed by computer processor 104. Key pad 34 is checked to make sure no inputs are being generated. More specifically, computer processor 104 checks to see if any of keys 110, 112, 114 or 116 are closed. If second key pad 34a is present, computer processor 104 sees the corresponding keys 110a, 112a and 116a (not identified, but see 34a on
During start up, computer processor 104 checks a specific location in its volatile memory to see if a specific key is stored there. If the specific key is stored there, it indicates that the volatile memory has not properly reset, such as might happen with a power glitch. Computer processor 104 terminates start up, inhibits operation of the lift, and enables the display of data indicative of the improper reset by computer processor 106. If the specific key is not stored in the specific volatile memory location, indicating proper reset, computer processor 104 will write the specific key to the volatile memory location.
After verifying the system status is OK, control 100, which powers up in the operating mode, may be used to control the raising and lowering of the moveable lift engagement structure.
Additionally, at start up computer processor 106 verifies the presence of an operable memory module 106a. If it is not found, display 32 will so indicate. Control 100 remains in the operating mode, with keys 110, 112 and 116 remaining functional. However, mode key 114 cannot switch modes to the information mode.
While in the operating mode, upon the transmission of any user input to control 100, such as through key pad 34, which would enable actuation of an actuator, computer processor 104 checks all of the inputs from user interface 31 and all other inputs as at start up to verify that they are in the correct state. Computer processor 104 also energizes all actuator drivers one at a time for a short time, about one millisecond, long enough for computer 104 to check to make sure that at least the threshold voltage is present in the voltage divider circuits at the actuator driver outputs before proceeding, but not long enough to actuate any of the actuators. When the moveable lift engagement structure is being raised or lowered, if there is any inconsistent user input, such as pressing the up and down keys simultaneously, movement of the moveable lift engagement structure will stop until all user input ceases.
Control 100, through computer processor 104, periodically monitors the actuator drivers for the correct state. If an actuator is supposed to be energized, computer processor 104 looks for the threshold voltage at that actuator driver. If an actuator is not supposed to be energized, even when another actuator is actuated, computer processor 104 looks for no voltage at that actuator driver.
The occurrence of operation fault conditions are also communicated to the user independent of whether display screen 32 is operative. To communicate such information, a code of beeps and LED flashes may be used. In the depicted embodiment:
In the depicted embodiment, all of the functions which control the operation of the lift (which does not include display of data by display screen 32) while control 100 is in the operating mode, are performed by first processor 104 independent of second processor 106. For example, the control logic is resident on first processor 104; sensors which monitor operation conditions are connected to computer processor 104; operation conditions not monitored through sensors are monitored through computer processor 104; the predetermined criteria on which the generation of an operation fault indication signal is based is resident on first processor 104; operation fault indication signals are generated by computer processor 104; communication of operation fault conditions independent of display screen 32 is done by computer processor 104; computer processor 104 generates the signals which enable second computer processor 106 to enable display of messages corresponding to operation fault conditions on display screen 32; and actuation of audible signal sounder 82 is done by computer processor 104.
Thus, control 100 is configured so that computer processor 104 controls all lift operations regardless whether computer processor 106 is present or functional. By configuring the lift operation control to be resident in a single computer processor and fully operational to control the lift independent of other processors which provide non-lift operation functions, changes may be made to the non-lift operation functions and any associated processors, programming and hardware without affecting or requiring changes to the lift operation control. Since lifts and controls for lift operation are subject to third party certification, this separation of the functions between lift operation control and non-lift operation functions allows changes to be made to the non-lift operation functions without requiring rectification of the lift operation control.
As previously mentioned, control 100, and more specifically computer processor 106 in the embodiment, depicted is also configured to enable display of data, in the depicted embodiment, through display screen 32. In this embodiment, control 100 has two modes, the operating mode, as described above, and the information mode. As previously indicated, control 100 powers up in the operating mode. To switch to the information mode, key 114 is actuated thereby transmitting a “mode” signal which enables computer processor 104 to transmit a signal to computer processor 106. In response to the signal from computer processor 104, computer processor 106 will transmit an appropriate responsive signal to computer processor 104. Upon receipt of the acknowledging responsive signal, computer processor 104 will enter the information mode. The same “handshake” protocol is followed in switching from the information mode to the operating mode.
While in the information mode, key pad 34 is not functional to control the lift operation, although computer processor 104 continues to monitor the operation conditions as described above. In the information mode, computer processor 104 transmits user input from key pad 34 to computer processor 106 to enable display of data in response thereto.
As mentioned above, keys 110, 112 and 116 are each configured to perform at least two functions: One set of functions may be performed while in the operating mode and a second set of functions may be performed while in the information mode. While in the information mode, the selection of data to be displayed is menu driven. In the information mode, display screen 32 displays menu options and keys 110 and 112 are used to scroll up or down through the menu. In this mode, key 116 is functional to select the menu option to which the user has scrolled.
Computer processor 106 is configured to enable display of lift data in response to user input received from key pad 34 via computer processor 104. Lift data as used herein includes any data relevant to the operation or control of the lift. The display of such lift data can include various display techniques to draw attention to or to emphasize desired aspects of the lift data being displayed, such as flashing graphics.
Lift data includes usage data and operation fault data, as described above. Lift data also includes data which instructs the user in regard to the lift (instructional data). Instructional data includes information on how to use the lift (use instruction data), on safety practices and warnings relevant to operation of the lift such as displaying safety decal information (safety data), and on how to troubleshoot operation of the lift (troubleshooting data).
In the depicted embodiment, lift data also includes maintenance data. Maintenance data includes maintenance notice data indicating that a maintenance condition exists and maintenance instruction data which includes information on maintaining the lift.
As mentioned above, computer processor 106 includes maintenance control logic which is operative to generate a maintenance condition indication signal, based on predetermined criteria, which enables display of maintenance data indicative of the maintenance condition. Maintenance conditions include conditions that call for preventative maintenance and conditions that call for repair maintenance.
In the depicted embodiment, the predetermined criteria used to base the generation of a maintenance condition indication signal is based on the passage of time: A specific maintenance condition indication signal is generated when the predetermined time period for that specific maintenance condition has passed. The following table provides examples of predetermined time period criteria for the indicated maintenance condition:
These time periods are purely illustrative. In this example, reminders for daily maintenance conditions (i.e., maintenance conditions that should be addressed daily) are set at 7 days, rather than daily. The weekly reminder may include an indication that the maintenance needs to be performed daily. Not all of the maintenance conditions listed in this table applies to all lift types. Additionally, different time periods may also apply for different lift types. The user selects the lift type in the information mode, which identifies the predetermined criteria applicable to the particular lift type. Lift type is also relevant to whether the latches 90 are mechanically operated by solenoid 88 or whether a solenoid operated pneumatic valve is used, so the proper actuation voltage is applied by the associated actuator driver.
As used herein, predetermined criteria, as related to maintenance conditions, includes criteria based on solely on the passage of a period of time, as well as criteria based on varying parameters related to the operation or environment of the lift, such as usage data. Such predetermined criteria includes, for example, algorithms which correlate usage data to the maintenance requirements of the lift as may be empirically developed. Additionally, such predetermined criteria may be based on operation fault data.
Upon generation of a maintenance condition indication signal, accompanied by display of the maintenance notice data, the user may either actuate the “select” key 116, which will then enable display of maintenance instruction data regarding that maintenance condition, or actuate the mode key 114, which will place control 100 in the operating mode. The maintenance condition may be reset at the appropriate display by input from the user through key pad 34, preferably only after the indicated maintenance has been performed. The maintenance notice data will be displayed once a day, for example in the morning when the lift has been powered up for the day. Each subsequent day after the initial display of the maintenance notice data, if the maintenance condition has not been reset, the display will indict the number of days the maintenance condition has been passed due. Alternatively, display of the maintenance notice data may be scheduled for a particular time of the day, which is particularly beneficial in case control 100 is left on overnight.
Control 100 includes time management functions. Control 100, through computer processor 106, includes a timer function which displays lapsed time on display screen 32 in all operation modes. The timer may be started and stopped by actuating the appropriate key while in the information mode. Alternatively, the time may be started automatically upon placing a vehicle on the lift and/or raising the lift. Control 100 also includes and displays date and time information, and an alarm which can be set to beep at a preset time on a one time or daily basis.
In addition to lift data, computer processor 106 is configured to enable display of vehicle lift point data, which is data indicating the location of the proper lift points for a vehicle. In depicted embodiment, vehicle lift point data is available for most vehicles less than twenty years old. In this embodiment, vehicle lift points are displayed in conjunction with a graphical representation of the vehicle.
While in the depicted embodiment, selection of vehicle lift point data displayed is done by user input to key pad 34, the display of vehicle lift point may be enabled in other ways. For example, data on the type of vehicle may be scanned, or transmitted by an RF or IR transmitter on the vehicle.
Control 100 may also be configured to display and receive various other data. Computer processor 106 may be configured to display service data regarding the vehicle. Service data includes any data relevant to performing service on the vehicle, such as instructions on servicing, service bulletins, specifications, time required for defined service, parts list, etc. Service data may include data about the service history of the specific vehicle. Control 100 may be configured to order parts based on input from the user from the facility's parts department, or even order directly from a parts supplier, with an appropriate communications connection, described below. Control 100 may be configured to keep track of the service performed and interface with an iqinvoicing system.
Control 100 may be configured to receive information identifying the user, such as through key pad 34, through a card reader or any means, and to keep track of the user's time spent on the particular job. Control 100 may further be configured to require input of an authorized user identification before the lift may be operated.
Lift data is stored in a non-volatile electronic memory. Such electronic memory may be a physical storage device such as a hard drive, tape drive, etc. Such electronic memory may also be a memory module, such as an EEPROM, or the like. In the depicted embodiment, usage data, as well as the predetermined criteria for operation conditions and lift type information are stored in a non-volatile memory of computer processor 104.
Instructional data and maintenance data are stored in memory module 106a carried by computer processor 106. The predetermined criteria related to maintenance conditions is also stored in a memory associated with computer processor 106. This allows changes to these data and criteria to be made without affecting any aspect of computer processor 104.
Any other data displayable by control 100 is also stored in a memory.
Referring now to
The functions performed by computer processor 106 described above are performed for the plurality of lifts by central computer processor 210 and memory 208. User input from the respective user interfaces (not shown in
Operation fault data, instructional data and maintenance data are stored in memory 208, as may be vehicle lift point data. Central computer processor 210 includes the maintenance control logic which, as described above, is operative to generate a maintenance condition indication signal, based on predetermined criteria, which enables display of maintenance data indicative of the maintenance condition. The predetermined criteria related to maintenance conditions is applied by central computer processor 201. For predetermined criteria based on usage data, central computer processor 210 “looks” at the respective usage data collected by the respective control 204. As with computer processor 106 as described above, storing the predetermined criteria in memory 208 provides greater flexibility to revising the criteria. By centralizing the data in memory 208, implementing revisions for all lifts is simpler. For example, revisions could be downloaded from the internet or other external communication.
Alternatively, central computer processor 210 may be omitted, with memory 208 providing common memory storage of data and maintenance control logic for the second computer processors (corresponding to computer processor 106 as described above) of all lift controls 204. This provides the advantages of a central memory.
Although as described above, the lift controls 204 networked to vehicle service system 200 all maintain the operation control logic locally (e.g., each has a respective first computer processor corresponding to computer processor 104 as described above), which is preferable, alternatively the operation control logic could be centrally located, with inputs and outputs being communicated over the network and with the user remaining local at the associated lift. Sensor outputs could be delivered over the network, while actuators could remain driven locally upon appropriate signal from the central computer processor 210.
Other equipment may be connected to network 206. For example, in addition to lift controls 204, equipment and tools which are suitable for use in servicing a vehicle or with a vehicle service system may be fitted with an electronic control appropriate for that tool and connected to the network.
Other computer systems could be connected to network 206, or network 206 could be part of or connected to a larger computer communication network to which other computer systems are connected. Such other computer systems could include for example parts ordering system, accounting/billing system, scheduling systems, etc. The network could be connected to other networks, such as the internet, for various reasons, such as to place parts orders or to download service data.
In summary, numerous benefits have been described which result from employing the concepts of the invention. The foregoing description of a preferred embodiment of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiment was chosen and described in order to best illustrate the principles of the invention and its practical application to thereby enable one of ordinary skill in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto.
This application claims priority from U.S. Provisional Application Ser. No. 60/243,827, filed Oct. 27, 2000, the disclosure of which is incorporated herein by reference.
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5299904 | Simon et al. | Apr 1994 | A |
5341575 | Chisum | Aug 1994 | A |
5679934 | Juntunen et al. | Oct 1997 | A |
5829948 | Becklund | Nov 1998 | A |
6286629 | Saunders | Sep 2001 | B1 |
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91 15 317 | Mar 1992 | DE |
0 615 645 | Sep 1994 | EP |
Number | Date | Country | |
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20020175319 A1 | Nov 2002 | US |
Number | Date | Country | |
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60243827 | Oct 2000 | US |