Controlling the Envelope of a Boom Lift

The working envelope of a boom lift includes all combinations of accessible height and outreach of the platform. It directly influences the stability and strength requirements of the machine.

Reach diagrams are published in the manual of each machine to give operators a visual understanding of the limits of the machine.

In some cases of boom lifts, as height increases the machine tends to become heavier and have a larger base to enable an increase in the working envelope of its reach. When designing a boom lift, vehicle weight is an important consideration because it affects manufacturing costs, vehicle maneuverability and safety factors.

An envelope control system is the primary means of controlling the stability of the machine by restricting the working envelope of the main boom. The envelope shape positions of stability and structural integrity can be controlled including the restriction of forward and rearward reach of the platform.

Each machine has its own envelope control. There are two ways to control the envelope of the main boom: Mechanically and electronically. Mechanical limitations are typically reserved for smaller machines as straight booms can use linkages to restrict the envelope control. Small articulated booms can take advantage of the functionality of the machine to restrict the envelope.

Envelopes that are limited electronically are more prevalent on larger models, especially those with a straight boom. The boom’s envelope is controlled electronically with sensors, whether they are length and angle sensors or load sensing devices. The sensors restrict the length of the boom based on its angle and vice versa. 

A stable machine has the envelope control system as one of its most important attributes. While there is a complexity to understanding how the system works, it is necessary to bring awareness to this process and understand what the machine is doing and why.

Mechanical Envelope Control
A conventional straight boom lift typically includes a single telescopic boom which enables the platform to be positioned from low angles (usually below horizontal) to high angles (around 75-degrees above horizontal). When an angle is near horizontal, it creates a situation of forward instability where the machine may tip toward the platform due to the moment created by the platform load and boom assembly. Counterweight can be added to the tail of the vehicle turntable to counterbalance the destabilizing moment created by the boom and platform load.

Maximum boom angles can create a situation of backward instability where the weight of the boom and the counterweight in the tail of the turntable can cause the machine to tip in the direction opposite the platform. Typically, counterweight is added to the frames of the machines to help counterbalance the destabilizing moment caused by the boom and tail counterweight. The total weight of the machine is dependent on the compromise made for the placement of weight required to satisfy both conditions of instability.

A single tower articulated boom lift typically includes two booms connected by an upright. This upright is held in a vertical orientation as the lower boom or tower is raised at an angle. Maintaining the upright in a vertical orientation is usually achieved by a hydraulic circuit or parallelogram linkage with the tower boom. The upper boom is pinned to the upright with its own lift cylinder which can be raised or lowered in angle with a full range of motion regardless of the position of the tower boom.

The two booms can be independently positioned to allow the machine to be used for various work positions and articulated for up and over obstacles. The total maximum height of the platform is achieved by the contribution of the tower and upper boom lengths. Booms on an articulated lift are typically shorter than the boom of a comparable height straight lift. Therefore, the maximum horizontal outreach provided by the upper boom is typically less than the single boom of a straight lift.

A position of maximum forward instability for this type of boom is encountered when the tower is raised to its full angle with the upper boom near a horizontal angle. This creates the maximum horizontal outreach of the platform while also positioning the boom structure weight in the most detrimental position to the forward stability of the machine. Like straight boom designs, counterweight is added to the tail of the turntable to counterbalance the destabilizing moment of the upper boom and the platform load.

Likewise, the position of maximum backward instability occurs when the tower is lowered to a near horizontal angle while keeping the upper boom raised at the max angle. The weight of the boom structure has moved to the most detrimental position of backward stability and is made worse by the presence of the tail weight added to reduce forward instability. Frame counterweight is typically added to counterbalance the additional weight.

Electronic Envelope Control
Some boom lifts have a tower boom coupled to the vehicle base with the tower boom having the capability of extension and retraction via telescope sections. Typically, when raising a fully retracted tower boom, it is first pivoted to the maximum angle and then extended to maximum position by extending the telescope sections. By raising the tower boom in this manner, a main boom supporting the platform that is coupled to the upper end of the tower boom may be placed in positions that create a large overturning moment.

To accommodate for large overturning moments, the vehicle must include a large mass counterweight to stabilize the machine. However, large counterweights increase manufacturing costs and could have a detrimental effect on operating envelopes. For example, when a vehicle is operating on an incline, it may not perform to the same capabilities as if it were on a level surface. Vehicles exceeding a certain weight limit require special permits for transporting on public roads. This results in additional costs to the vehicle.

Forward stability positions are the most critical when the main boom is extended near a horizontal angle and when the tower is fully raised in angle but retracted in length. Backward stability positions are most critical when the main boom is fully raised while the tower is lowered and retracted or when the tower is fully raised and fully extended.

With the addition of sensors, the boom positions are continuously measured, and the position is controlled within the predetermined envelope. The system uses two main boom angle sensors, a main boom length sensor and a main boom transport length switch.

The two main boom angle sensors measure the angle of the main boom relative to gravity and are continuously monitored for mutual agreement. The main boom length sensor measures the length of the main boom and is monitored for response to the main telescope command and for agreement with the fixed position length switch.

Violations of the main boom position to allowable envelope positions will result in reduced function speeds, a boom control system (BCS) warning light illumination and restriction of functions. The platform alarm will sound and the BCS light will flash with attempts to operate restricted functions. The machine will be restricted from leaving the transport position until the failure is resolved.

Envelope control is important to the industry because it provides the opportunity to make taller machines without the need to add excessive outreach and excessive weight.

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