Non-Structural High Voltage Batterylink

Last updated: December 11, 2024

Overviewlink

The high voltage (HV) battery is the primary energy storage device in the vehicle. Its main purpose is to provide power to the powertrain for all vehicle operations.

The HV battery hosts several key components of the powertrain that are vital for vehicle functions like driving, charging, and providing power to the vehicle low or medium voltage (referred to as LV or MV) systems.

Warning

The HV battery has a lot of energy stored in a small volume. Use extreme care when handling HV batteries.

Location of the High Voltage Batterylink

The HV battery is mounted to the chassis bottom for easy removal and installation, improving vehicle dynamics with a lower center of gravity.

The HV battery is not designed for rapid HV battery swapping, nor does it have HV rapid mate connectors between the HV battery and the HV powertrain. The HV battery has latch-on HV connectors, and the coolant hose connections are clamped (not via rapid mate).




1. Front of vehicle 2. Rear of vehicle 3. HV battery
HV Battery Location

Pack Generationslink

Below are the different generations of Tesla HV batteries:

HV battery Generation	Applicable Models
Gen 1	2012-2020 Model S 2015-2020 Model X
Gen 2	Model 3 Model Y (Non-Structural and structural HV batteries)
Gen 3	2021+ Model S 2021+ Model X
Gen 4	Cybertruck

The Gen 3 HV battery was introduced on the 2021+ Model S and Model X vehicles. At launch in early 2021, there was only one configuration of the HV battery for both Long Range (Dual Motor) and Plaid (Tri-motor) configurations. The same HV battery can be used for all configurations and all markets (three-phase and single-phase) by using a dummy plug at the HV battery on the second rear HV drive unit connector for the Long Range (Dual Motor) configuration and another dummy plug on the 3-phase connector

Note

Until mid-2022 when 2021+ Model S and Model X vehicles were shipped to EMEA and APAC, the HV battery produced was North America only and did not have a 3-phase plug.

Pack Architecturelink

The HV battery consists of the four distinct sections:

The module platter
The Ancillary Bay
The rear access service panel
The pyro-disconnect area

The HV battery module platter includes battery cells and thermal management components, and the Ancillary Bay holds electronic components known as "high voltage devices." For more details, see HV Devices Theory of Operation.


1. Front Ancillary Bay 2. HV battery Platter (under the cover) 3. Rear Access Service Panel 4. Rear Access Service Panel Cover 5. Front Ancillary Bay Service Cover 6. HV Battery Enclosure
HV Battery Architecture Sections (With Service Access Shown)

Battery Platterlink

The HV platter is the large area of the battery that is below the Ancillary Bay and inside the enclosure. It contains the modulesmodules See item number 2 on the figure above to locate the platter.

The platter contains all the cells which have a minimum voltage of 2.5V4.2V110, the HV battery has a minimum voltage of 275V and a maximum of 462V

The cells used in the HV battery have 12.84 Wh101.6 kWh Ancillary Bay Theory of Operation.

Ancillary Baylink

The Ancillary Bay contains most of the HV electronics in the HV battery used to control the HV system of the vehicle. This includes:

Powering up the HV system of the vehicle
Charging the vehicle HV battery
Providing power to the low- modules

The Ancillary Bay contains:

HV Device	Purpose
Power Conversion System (PCS)	Converts AC to DC when charging Converts DC to DC to support thelow- Includes the High Voltage Battery Management System (HVBMS) and High Voltage Processor (HVP)
HV Pyro-disconnect	Disconnects HV when specific HV failure is detected (previously called a pyro-fuse)
Charge inlet connector	Connects PCS input to the charge port
HV fuses	Switched PCS HVDC input/output


1. Front Ancillary Bay cover 2. PCS 3. Tray for PCS mounting 4. Front Drive Unit HV connector 5. Heat pump compressor HV connector 6. High voltage controller 7. Shunt 8. Pyro-disconnect 9. Negative contactor 10. Coolant manifold for module coolant loop
Exploded View of Front Ancillary Bay Components



1. Platter coolant input manifold 2. Platter coolant output manifold 3. Front drive unit HV connector 4. Heat pump compressor 63A fuse 5. PCS 63A fuse 6. Heat pump compressor HV connector 7. Compressor EMI noise reducer 8. High voltage controller 9. Shunt 10. Pyro-disconnect 11. Negative contactor
Detailed View of Ancillary Bay Internals

The pyro-disconnect is accessible after removing the entire Ancillary Bay cover when the pyro-disconnect trips and needs replacement (usually after any airbag or pretensioner deployment).

The front Ancillary Bay has a service access cover allowing quick access to the HV devices within the Ancillary Bay . The cover is removable and can be found once the HV battery has been dropped from the vehicle.

A dedicated cover under the vehicle allows for easy access to the pyro-disconnect, enabling replacement without removing the HV battery or Ancillary Bay cover, often after any airbag or pretensioner deployment.


1. Front Ancillary Bay with its access cover
Front Ancillary Bay

High Voltage Interfaceslink

The HV battery integrates the functionality of the on-board charger, DCDC converter, High Voltage Junction Box (HVJB), and Front Junction Box (FJB) low-

1. HV Plug for Rear Drive Unit HV cable (connector reference RDULEFT-HV-AT-HVBATT)
2. HV Plug for Right Rear Drive Unit HV cable (connector reference RDURIGHT-HV-AT-HVBATT) - Dummy plug for Dual Motor configurations
3. Three phase charge inlet connector
4. Charge inlet connector
5. PCS coolant inlet passthrough
6. Platter coolant passthrough
7. Logic connector
8. 12V passthrough
9. Front Drive Unit connector at HV battery (connector reference FDU-HV-AT-HVBATT)
10. Ancillary HV connector (connector reference CMP-HV-AT-HVBATT)
11. PCS coolant outlet passthrough

HV battery interfaces

Moduleslink

Specificationslink

The HV battery is made of 5 independent modules that are seated in the entire width of the HV battery enclosure.

The module contains the cells of the HV battery and it is the source of energy and power for the vehicle.

Each module is made of 22 bricks in series which sums up to a voltage of 80V per module. A brick contains a group of 72 cells connected in parallel. The Model S and X (2021+) HV battery has one unique module part number, the 5 modules are identical.x`


1. Module 1 (most negative) 2. Module 2 3. Module 3 4. Module 4 5. Module 5 (most positive)
HV Battery Modules in the Platter

Operationlink

Cellslink

Cells are the source of energy and power for the vehicle.

The HV battery has an internal structure of lithium ion cells linked together in combination of parallel and series to reach the desired level of energy and power required.

The lithium ion cells have a high energy density (Wh/kg), about 2 to 3 times the energy density of a nickel-metal hydride battery and 6 times the energy density of lead acid battery. Lithium ion cells are agnostic to charge and discharge patterns. When not in use, lithium ion cells self-discharge and have a flat discharge curve, meaning they have linear power capability even at half charge level.

Rechargeable batteries perform reversible electrochemical reactions at the battery’s positive and negative electrodes. The battery is charged by applying an electric current.

During discharge, lithium ions de-intercalate from the negative electrode and move through a separator to intercalate in the positive electrode. When charging, the reverse occurs. Lithium ions de-intercalate from the positive electrode and move through a separator to intercalate in the negative electrode.

The cells used in the HV battery have a 18650

HV battery Generation	Configuration	Cell Type	S-Count	P-Count	Total Cells in Pack
Gen 3	Plaid / Long Range	18650	110	72	7920

Bricks in Bandolierslink

A brick is a group of cells connected in parallel. Linking cells in parallel adds current from each cell to increase current capability and the amp hour count (the unit for measuring the energy capacity of a battery).

The bricks are connected in series in a module to increase voltage. The modules are also chained together in series to further increase voltage and power capability.

A bandolier refers to one or two strings of cells against a cooling tube. A module is made of 11 bandoliers.

Note

Cells on the HV battery are close to each other and could end up touching. To prevent a brick to brick short, each cell of a HV battery module has an insulating sleeve around it. Each side of the bandolier is wired fully in parallel as one single brick. Each bandolier is two bricks, one on each side of the cooling tube.


1. Module 2. One bandolier 3. Next bandolier
Bandoliers per Module

The bricks are made of one row of cells that runs the entire width of the module. This allows for linear current flow among the cells without spots where current would get concentrated, like bolted joints.

The diagram below shows 2 bricks mounted on a bandolier with 72 cells per side.


1. Single bandolier 2. First 72 cell brick of the bandolier 3. Second 72 cell brick of the bandolier.
Two Bricks per Bandolier

The cells in the bandolier are positioned vertically and oriented in both directions (one brick with anode facing up and the next brick with anode facing down).

The size and orientation of the cells are reconstituted from the predecessor Gen 2 pack:

The cells are 1865 type, measuring 18mm in diameter and 65mm in height, with internal differences from Gen 2 cells that enable increased power.
By contrast, the Model 3 / Model Y HV battery uses a 2170 cell format, or 21mm in diameter and 70mm in height.
The Model S and X (2021+) HV battery cells are positioned vertically in the module and oriented in both directions (one brick with anode facing up, and the next brick with anode facing down).

Note

that this is different from the Model 3 / Model Y HV battery, where all cells are oriented in the same direction.

Each brick's cells are connected in parallel to dual current strips (positive and negative) on both the top and bottom, enabling efficient current collection.

Brick interconnects, also known as "dog bones," connect adjacent bricks along the bandolier, facilitating electrical connections between them (only present on the top side of the module).


1. Module current collectors (connected to module terminals) 2. Brick interconnects (sometimes referred to as "dog bones") 3. Current strips linking cells into a brick (orange)
Two bricks per bandolier

Each module has a long battery monitoring board (BMB) that runs its entire width (the predecessor Gen 2 HV battery module had a much smaller BMB). Each Model S and X (2021+) HV battery BMB is connected to each brick of the module to measure all 22 brick voltages. The brick pattern of the Model S and X (2021+) HV battery module allows the BMB to directly connect to the current strips without using any leads. This direct connection lowers the risk of voltage sense harness issues from severed sense leads.

The BMB is also equipped with two thermistors to measure temperature of the module. The two thermistors are located on the side of the BMB PCBA that is against the module. The location is close to the extremity of the cooling tubes compared to the manifold (on the opposite side of the module compared to the BMB).

Modules are separated by a cross member running length wise in The HV battery. There are three inner longitudinals between each module and two outer longitudinals between the outer modules and the edge of the battery. The outer longitudinal protects the modules during side vehicle impacts.

The top of the cells of each brick are spot welded to two current collectors.

One current collector is connected to two bricks (positive of one brick and negative of the other one).
A single collector will be connected to cells.
Half of a collector will be connected to the can of the cells (anode) and the other half are connected to the center tab (cathode).

The current collector performs the following functions:

Electrically interconnects cell-arrays in a series of parallel groupings,
Distributes current between all cells in a given parallel grouping,
Allows terminal voltage sensing, at a single point, for all cell in a given brick,
Conducts peak and continuous operating currents between each cell and array,
Fusing protection for HV shorts.

High Voltage Chainlink

Current and power accumulate along the cell-array, beginning at the first brick on the most negative end and growing to the positive end of the array, with HV terminals at each end to facilitate connection.

Note

The front terminals are designed to fuse under short circuit events at the cell-array level.

For detailed information on how the voltage builds up in the HV battery, refer to the HV Architecture Theory of Operation

Serviceabilitylink

Modules are not serviceable because they are embedded within the platter area, making them inaccessible due to the structural HV battery's bonded top and bottom enclosures.