Here are the different types, available from garage equipment supply dealers:

In-Ground

This type of vehicle lift is assembled below the garage floor. It consists of one or more pistons, depending on the maximum weight capacity. Lifts with one or two pistons are used for compact, mid-sized and full-sized cars. Lifts with three or more pistons are used for larger vehicles, such as buses and RV’s.

Two Post Surface Mounted

The most common vehicle lift utilized today is called a Two Post Surface Mounted lift. On each column, there are lift arms. These are controlled mechanically, electronically or hydraulically.

Multi-Post Runway Automotive Lift

The most common type is the four-post mounted lift, which is extensively used by oil change, transmission, and muffler service shops. You’ll find this type of auto lift in wheel alignment service stations as well. The car is driven onto the two runways and raised, exposing its underside.

Low/Mid Rise Frame Engaging Lift

This type of vehicle lift engages the vehicle’s frame in lifting. There are two ways this type may operate. One way is scissors-style, moving straight up. Another is parallelogram-style, moving forward or backward, while raising or lowering. This type is commonly used for brake, tire, and wheel services as well as auto body repair.

Drive-On Parallelogram

The Drive-On Parallelogram is a surface-mounted vehicle lift. It has two runways where the wheels of the car should be placed. It has a lifting mechanism that moves the vehicle a short distance forward or backward while raising or lowering. The direction depends on the way the lift is mounted.

Scissor Lifts

The Scissor Lift can either be of a fixed pad type or a roll-on frame/underbody engaging type. It has a lifting mechanism that’s similar to the parallelogram lift. Their main difference is that the scissors lift goes up and down on a straight vertical path.

Movable-Type Wheel Engaging Lift

This type of vehicle lift is used for vehicles that are longer than conventional cars, such as buses and trucks. It consists of several lifting columns in sets of two, four, six, or more. The columns can be moved and connected with the other columns so that their movements are synchronized.

 

The KWP2000 protocol has become a de facto standard in automotive diagnostic applications. It is standardized as ISO 14230-3. KWP2000 describes the implementation of various diagnostic services you can accethrough the protocol. You can run KWP2000 on several transport layers such as K-line (serial) or CAN.

Transport Protocol

As KWP2000 uses messages of variable byte lengths, a transport protocol is necessary on layers with only a well defined (short) message length, such as CAN. The transport protocol splits a long KWP2000 message into pieces that can be transferred over the network and reassembles those pieces to recover the original message.

KWP2000 runs on CAN on various transport protocols such as ISO TP (ISO 15765-2), TP 1.6, TP 2. 0 (Volkswagen), and SAE J1939-21. For KWP2000, the Automotive Diagnostic Command Set supports only the ISO TP (standardized in ISO 15765-2) and manufacturer-specific VW TP 2.0 transport protocols.

Diagnostic Services

The diagnostic services available in KWP2000 are grouped in functional units and identified by a one-byte code (ServiceId). The standard does not define all codes; for some codes, the standard refers to other SAE or ISO standards, and some are reserved for manufacturer-specific extensions. The Automotive Diagnostic Command Set supports the following services:

• Diagnostic Management

• Data Transmission

• Stored Data Transmission (Diagnostic Trouble Codes)

• Input/Output Control

• Remote Activation of Routine

Upload/Download and Extended services are not part of the Automotive Diagnostic Command Set.

Diagnostic Service Format

Diagnostic services have a common message format. Each service defines a Request Message, Positive Response Message, and Negative Response Message. The Request Message has the ServiceId as first byte, plus additional service-defined parameters. The Positive Response Message has an echo of the ServiceId with bit 6 set as first byte, plus the service-defined response parameters.

The Negative Response Message is usually a three-byte message: it has the Negative Response ServiceId as first byte, an echo of the original ServiceId as second byte, and a ResponseCode as third byte. The only exception to this format is the negative response to an EscapeCode service; here, the third byte is an echo of the user-defined service code, and the fourth byte is the ResponseCode. The KWP2000 standard partly defines the ResponseCodes, but there is room left for manufacturer-specific extensions. For some of the ResponseCodes, KWP2000 defines an error handling procedure. Because both positive and negative responses have an echo of the requested service, you can always assign the responses to their corresponding request.

Connect/Disconnect

KWP2000 expects a diagnostic session to be started with StartDiagnosticSession and terminated with StopDiagnosticSession. However, StartDiagnosticSession has a DiagnosticMode parameter that determines the diagnostic session type. Depending on this type, the ECU may or may not support other diagnostic services, or operate in a restricted mode where not all ECU functions are available. The DiagnosticMode parameter values are manufacturer specific and not defined in the standard. For a diagnostic session to remain active, it must execute the TesterPresent service periodically if no other service is executed. If the TesterPresent service is missing for a certain period of time, the diagnostic session is terminated, and the ECU returns to normal operation mode.

GetSeed/Unlock

A GetSeed/Unlock mechanism may protect some diagnostic services. However, the applicable services are left to the manufacturer and not defined by the standard.You can execute the GetSeed/Unlock mechanism through the SecurityAccess service. This defines several levels of security, but the manufacturer assigns these levels to certain services.

Read/Write Memory

Use the Read/WriteMemoryByAddress services to upload/download data to certain memory addresses on an ECU. The address is a three-byte quantity in KWP2000 and a five-byte quantity (four-byte address and one-byte extension) in the calibration protocols. The Upload/Download functional unit services are highly manufacturer specific and not well defined in the standard, so they are not a good way to provide a general upload/download mechanism.

Measurements

Use the ReadDataByLocal/CommonIdentifier services to access ECU data in a way similar to a DAQ list. A Local/CommonIdentifier describes a list of ECU quantities that are then transferred from the ECU to the tester. The transfer can be either single value or periodic, with a slow, medium, or fast transfer rate. The transfer rates are manufacturer specific; you can use the SetDataRates service to set them, but this setting is manufacturer specific. The Automotive Diagnostic Command Set supports single-point measurements.

Diagnostic Trouble Codes

A major diagnostic feature is the readout of Diagnostic Trouble Codes (DTCs). KWP2000 defines several services that access DTCs based on their group or status.

Input/Output Control

KWP2000 defines services to modify internal or external ECU signals. One example is redirecting ECU sensor inputs to stimulated signals. The control parameters of these commands are manufacturer specific and not defined in the standard.

Remote Activation of a Routine

These services are similar to the ActionService and DiagService functions of CCP. You can invoke an ECU internal routine identified by a Local/CommonIdentifier or a memory address. Contrary to the CCP case, execution of this routine can be asynchronous; that is, there are separate Start, Stop, and RequestResult services. The control parameters of these commands are manufacturer specific and not defined in the standard.

External References

For more information about the KWP2000 Standard, refer to the ISO 14230-3 standard.

Some people think that automotive fasteners are only useful in automotive industries because of its name. However, such items are also depended upon by aerospace, petrochemical, waste processing, pharmaceutical and even machine industries. Typically, a fastener is derived from materials most specifically metals like iron, aluminum, brass, nickel and stainless steel.

Automotive fasteners are defined as mechanical components in order to hold two or more structures together. They are classified further as nuts, screw, rivets, studs, pins and tie rods. Each of these classifications has its own distinct characteristics. More facts on some of these types of fasteners are discussed in detail through the succeeding paragraphs.

Automotive nuts

Nuts are examples of fasteners used in order to secure a bolt or screw to a certain surface. Depending on the application where it is to be utilized, the nut is classified. Some examples of nuts are also classified depending on its shape and design. In this regard, subcategories include hex nuts, wing nuts, cap nuts and t-nuts. Lug nuts, plate nuts, jam nuts and self-locking nuts are also popular in a lot of automotive industries.

Automotive bolts

These are generally classified as threaded automotive fasteners with threaded pins or rods. Typically, it is easy to detect a bolt because it contains a head on one of its end. Bolts are offered in the market in different sizes and may only be placed depending on the hole’s size where it is to be used. The most common types of automotive bolts are wheel bolts, U-bolts, mounting plate bolts and hub bolts. Rod bolts, lug bolts and radiator bolts are also included in the list.

Automotive washers

Just by hearing the term washer, one may not be able to comprehend well about why it is classified under the list of auto fasteners. Well, automotive washers are those that have small and flat dishes containing holes on its center and are used to hold a load of automotive bolts. It is often found below the nut or the joint in order to prevent leakage as well as distribute pressure. Common examples of automotive washers are bolt lock, hardened, cylinder head, lug nut and radiator washers.

Other types of fasteners

Aside from the three types elaborated above, there are yet other forms of fasteners offered in the market. Studs, for instance are those that have double-ended features and are fastened at both ends. These fasteners are classified according to where they are used and the material utilized to make up such industrial products. Other automotive fasteners are rivets, screws and tie rods.

Automotive equipment and tools are a very important part of the automobile industry. They can range from simple hand held devices to large structures that can even lift a heavy truck. The uses of these equipments in the world of automobiles cannot be undermined. For carrying out repairs, for changing a tire, for lubricating, for servicing, for charging up the battery, and for cleaning the vehicles, these equipments are very important.

Here Is A Brief Note On Some Of The Uses Of These Equipments.

Automobile Equipment Usage

* Automotive Lifts: Hydraulic lifts are very common in the industry and are used in showrooms, repair shops, and automobile factories. They generally come in the form of a platform fixed on a zigzag leg that can be raised or lowered as required. Heavy vehicles can be raised by the use of this equipment. These are how cars reach the first or second floor of a showroom or how the repairs to the lower part of vehicles are carried out in a mechanic’s shop. These lifts can be of different types like motorcycle lifts, runway lifts, drive on lifts, in-ground lifts, etc.

* Lubrication Equipments: As the name suggests, these are used to lubricate parts of the vehicle. There is a long list of lubrication equipments available and each is used for different lubrication purposes. Oil and grease reels, grease guns, oil drains, and oil and grease pumps are all examples of such commonly used equipment. Blacrank is a good brand when it comes to these equipments. Blacrank oil pumps are indisputable masters of the group.

* Compressors: Air compressors are used to do various works on automobiles. Generally, air compressors give additional pressure to drive in screws and give more power to tools like wrenches and nail guns. These are also used to remove dirt from the vehicle.

* Service Equipments: A vehicle needs to be serviced from time to time to ensure its proper running. This is where service equipments come in. These are battery chargers, fuel transfer device, brake fluid exchangers, coolant service equipment, tire changers, etc.

* Reels: These come in different shapes and sizes and are an important member of any automotive equipment list. Reels could be air reels, exhaust hose reels, grease reels, etc. Reels help to keep the pipes and hoses in place and also to extend its life. They can be easily reeled out to the required size and stored by reeling back.

* Jacks: Jacks are important not only in the shop but also for every vehicle owner. They enable the person to lift up the vehicle for the purpose of changing tires or doing some emergency repairs on the vehicle.

The list of automotive equipment is quite long and their uses quite large. Companies who sell such equipments also deal in car parts, thus making the store a one stop place for all things related to automobiles. Nowadays, there are thousands of online stores selling these equipments making them more accessible to all in need.

Vehicle History Overview

  • They don’t make them like they used to.

The First Cars

  • The first motor cars were nothing more than a buggy and engine (Generally repaired by blacksmiths and carpenters. These cars were very expensive, which only the wealthy could afford)
  • Model T was the first car mass production on an assembly line in 1908 (Ford’s Vision was to produce an affordable car the average person could purchase)
  • Model T’s came in black only to keep the costs down. (The price came down once the assembly line was streamlined, but in 1908, the cost for a Model T started at $825. By 1913 the cost of the car reduced to $550)

Cars in the 1960s

Cars were made the same basic way up through the 60s

  • Body Over Frame
  • Rear Wheel Drive (Same concept, but the cars were very big, bulky, and heavy)

Except people in the 60s wanted SPEED! They achieved this with Big Block Motors, which created a lot of Horsepower. (The Birth of Hotrods, Rat Fink, Flames, and Pin Striping).

Cars in the 1970s

  • The government place strict fuel economy and emissions control laws
  • Customers demanded cars with increased fuel economy
  • New laws and customer demands started the automotive explosion of engineering ideas and changes in the automotive industry

Changes to comply with Demands and Laws

  • Smaller bodied cars and smaller engines
  • Aerodynamics (Increase Fuel Mileage)
  • Lighter cars by using different materials and designs
  • More work-hardened areas created during formation of panel (Body Lines)
  • Safety

Construction of Interstate Highways + Higher Speed Limits + More High Performance Cars = Accidents and More

Deaths from Auto Accidents

Federal Laws were passed to regulate safety. These laws included:

  • Installation of seatbelts
  • Safety glass windshields
  • Head restraints
  • In 1979, the first driver side airbag was introduced
  • Airbags are mandatory in motor cars produced after 1990
  • Unibody Torque Boxes: Allow controlled twisting and crushing
  • Crush Zones: Made to collapse during collision (To act as an absorber, absorbing the impact)

Modern Day Cars

  • Carbon Fiber Parts
  • Aluminum Parts
  • More Plastic Parts
  • High Strength Steel
  • Boron Steel
  • Unibody Construction
  • Space Frame Construction
  • Computer
  • Hybrid Cars

Now they even have cars that will tell you when you’re lost, where to turn, Parallel Park for you.

Conclusion

While the modern day cars appear to be made cheap and unsafe, they are actually designed to crush or collapse, while transferring the energy around the stronger passenger compartment to protect the passengers from injury.

There is considerably more damage to modern day cars during a collision than the older vehicles, which gives the perception that “they don’t make them like they used to”. However, in reality the cars are taking the impact instead of the passengers.

The lesson was designed to give you a little history, but to also emphasize that just a hammer, dolly and a few wrenches are not going to repair today’s cars. We need highly trained collision repair and automotive technicians to repair today’s vehicles.