Gear Pump Troubleshooting for Leakages and Pressure Drops

Gear pumps are widely used in hydraulic systems, lubrication systems, chemical transfer applications and

general industrial fluid handling. When a gear pump develops leakages or pressure drops, system performance

and reliability are immediately affected. This in?depth guide explains how to troubleshoot gear pump

problems related to internal and external leakage, pressure loss, poor efficiency and unstable operation.

All information provided here is brand?neutral and suitable for general industrial use.

1. Overview of Gear Pumps

A gear pump is a positive displacement pump that transfers fluid by using meshing gears. It delivers a

nearly constant flow rate at a given speed, regardless of discharge pressure (within design limits). Gear

pumps are simple, compact, and robust, which makes them ideal for applications where reliability and

predictable performance are critical.

1.1 Basic Principle of Operation

In a typical gear pump, fluid is trapped between gear teeth and the pump housing and then carried from the

suction side to the discharge side. As the gears rotate, they create expanding volume at the inlet (which

draws fluid into the pump) and decreasing volume at the outlet (which forces fluid out).

1.2 Types of Gear Pumps

Gear pumps can be broadly divided into two main types:

External gear pumps – Two identical external gears mesh together inside a close-fitting housing.

Internal gear pumps – An external gear meshes with a larger internal gear (or rotor) with the teeth facing inward, usually with a crescent-shaped spacer.

1.3 Typical Gear Pump Applications

Hydraulic power units and mobile hydraulic systems

Lubrication systems for bearings, gearboxes and engines

Chemical and polymer transfer and metering

Fuel oil transfer and burner feed systems

Process industry fluid circulation and filtration systems

1.4 Advantages Relevant to Leakages and Pressure Drops

Simple construction with few moving parts, reducing leak paths.

Tight internal clearances for good volumetric efficiency and low internal leakage.

Good performance over a wide viscosity range when correctly selected.

Self-priming capability under suitable suction conditions.

2. Key Definitions: Leakages and Pressure Drops

Effective gear pump troubleshooting requires clear definitions of leakage and pressure drop. These terms

are often used loosely, but in technical troubleshooting they have specific meanings.

2.1 Internal vs. External Leakage

Leakage Type	Description	Typical Symptoms	Main Causes
Internal leakage	Fluid bypasses within the pump from high?pressure zone back to low?pressure zone.	Reduced flow rate, lower pressure, increased heating, lower volumetric efficiency.	Clearance wear, erosion, scoring, distorted housing, low viscosity.
External leakage	Fluid escapes from the pump to the environment or to non?intended areas.	Visible oil leakage, contamination risk, oil level drop, safety hazards.	Damaged seals, cracked housing, loose fittings, improper assembly.

2.2 Pressure Drop vs. Pressure Loss

In gear pump troubleshooting, technicians commonly observe a “pressure drop”. This can refer to:

Pressure drop across the pump: Difference between discharge and suction pressures.

Pressure drop in the system: Losses across piping, valves, filters and other components.

Unexpected pressure reduction: System can no longer reach the required pressure level.

2.3 Efficiency Terms

Parameter	Definition	Relation to Leakages and Pressure Drops
Displacement (V_d)	Theoretical volume displaced per revolution (e.g. cm3/rev).	Basis for calculating expected flow; used to identify internal leakage.
Theoretical flow (Q_th)	V_d × speed (N).	Compare with measured flow to estimate internal leakage.
Volumetric efficiency (η_v)	Actual flow / theoretical flow.	Reduced by internal leakage and cavitation; key troubleshooting indicator.
Overall efficiency (η_o)	Hydraulic output power / mechanical input power.	Affected by leakages (volumetric) and friction (mechanical losses).

3. Common Gear Pump Symptoms: Leakages and Pressure Drops

When a gear pump experiences leakages or pressure problems, it often exhibits multiple symptoms at the same time.

Proper troubleshooting begins by recognizing and documenting all observable issues.

3.1 Symptom Checklist

Inability to reach required system pressure.

Pressure fluctuating or pulsating beyond normal limits.

Noticeable external oil leakage around shaft, cover, or connections.

Hot pump casing or unusually high oil temperature.

Excessive noise: whining, grinding, or cavitation sounds.

Slow actuator movement or reduced machine speed.

Foaming in reservoir or aerated oil.

Increased energy consumption for the same output.

3.2 Quick Diagnostic Matrix

Observed Symptom	Likely Root Cause Group	Priority Checks
Low pressure, low flow, no visible external leakage	Internal leakage, wear, wrong viscosity.	Flow test, temperature check, viscosity verification.
Low pressure, normal temperature, visible oil around shaft	Shaft seal failure, misalignment, overpressure.	Inspect seal condition, check coupling alignment, verify relief valve.
Pressure fluctuates, pump noisy, foamy oil in tank	Suction problems, air ingress, cavitation.	Check suction line, strainer, oil level, suction height.
High temperature, high noise, gradual loss of performance	Excessive internal leakage, overload, wrong fluid.	Measure current draw, verify fluid type, inspect pump clearances.

4. Root Causes of Gear Pump Leakages

4.1 Internal Leakage Causes

Internal leakage is a major source of gear pump pressure drops and efficiency loss. It occurs wherever there

are clearances between gears and housing, between gear ends and side plates, or across wear plates and

bushings.

4.1.1 Wear of Gear Teeth and Side Plates

Abrasive contamination erodes tooth flanks and tips.

Insufficient lubrication leads to scoring and galling.

Prolonged operation at high pressure causes plastic deformation of components.

As clearances increase due to wear, internal bypass paths enlarge. This increases internal leakage, reduces

delivered flow, and demands higher input torque.

4.1.2 Housing and Bearing Wear

Worn bearings allow shafts to move radially, opening clearances.

Misalignment causes uneven contact and localized wear.

Thermal expansion mismatch can distort the housing.

4.1.3 Fluid Viscosity Too Low

High temperature or wrong fluid grade decreases viscosity.

Low viscosity reduces the fluid’s ability to seal clearances.

Internal leakage increases dramatically at low viscosities.

4.2 External Leakage Causes

4.2.1 Shaft Seal Failures

Excessive shaft run?out or misalignment.

Overpressure in the pump casing or seal chamber.

Incorrect seal material for the fluid or temperature.

Improper installation or damaged seal faces.

4.2.2 Gasket and O?Ring Problems

Incorrect gasket material or hardness.

Age?related hardening, cracking or compression set.

Over?torqued or under?torqued housing bolts.

Chemical incompatibility with the fluid.

4.2.3 Cracked or Damaged Housing

Mechanical impact during handling or installation.

Thermal shock from rapid temperature changes.

Fatigue due to repeated overpressure or vibration.

5. Root Causes of Gear Pump Pressure Drops

A pressure drop in a gear pump system can originate within the pump itself or in the connected hydraulic or

process circuit. Accurate pressure troubleshooting requires distinguishing between pump?related and

system?related losses.

5.1 Pump?Related Pressure Drops

5.1.1 Severe Internal Leakage

When internal leakage passes a critical level, the pump cannot build the required pressure at the available

speed and displacement. This appears as a permanent pressure deficit even with no external leakage.

5.1.2 Excessive Clearances from Wear or Incorrect Assembly

If assembly tolerances are not respected during maintenance, side clearances and end clearances may exceed

design values, creating uncontrolled leakage paths.

5.1.3 Cavitation and Aeration

Cavitation: Local boiling of fluid due to low pressure at pump inlet causing vapor bubbles that collapse in the high?pressure region.

Aeration: Air entering the system from leaks in the suction line or low reservoir level.

Both phenomena reduce effective flow, cause pressure instability, and damage internal surfaces,

aggravating leakage over time.

5.2 System?Related Pressure Drops

5.2.1 Restrictions in Discharge Line

Clogged filters or strainers.

Partially closed isolation or control valves.

Undersized piping or long lines with high friction.

Excessive system resistance may prevent the pump from achieving its rated flow and pressure, or trigger

relief valve opening at lower pressures.

5.2.2 Relief Valve Malfunction

Relief valve stuck partially open due to contamination.

Incorrectly set relief pressure below needed system pressure.

Worn valve seat or pilot leaks, back?bleeding flow to tank.

5.2.3 Suction Side Problems

Clogged suction strainer reducing net positive suction head (NPSH).

Excessive suction lift or small?diameter suction piping.

Air ingress at fittings, gaskets or flexible hoses.

Suction problems manifest as pressure fluctuations, noise, and gradual performance decline.

6. Step?by?Step Gear Pump Troubleshooting Procedure

The following structured procedure helps technicians locate and correct gear pump leakages and pressure drops

efficiently. It is suitable for hydraulic gear pumps, lubrication gear pumps and general industrial gear pump

installations.

6.1 Preliminary Safety and Preparation

Isolate power and lock out the drive where required.

Depressurize the hydraulic or process system safely.

Clean external surfaces to reveal leakage paths clearly.

Prepare tools: pressure gauges, flow meter, infrared thermometer, dial indicator, torque wrench.

6.2 Visual Inspection for External Leakages

Inspect shaft seal area for oil tracks, spray or residue.

Check housing joint faces, cover plates and bolts for wetness or oil staining.

Examine port connections and fittings for drips or sweating.

Look for cracks, corrosion or mechanical damage on the pump body.

6.3 Pressure Measurements

Install calibrated gauges on suction and discharge ports if not already present.

Start the pump and allow it to reach normal operating temperature.

Record suction pressure, discharge pressure and reservoir temperature at several load conditions.

Compare values with design or historical reference data.

6.4 Flow and Efficiency Testing

Flow measurement is critical for quantifying internal leakage. Use a portable hydraulic tester or in?line

flow meter where possible.

Determine pump displacement and speed to calculate theoretical flow.

Measure actual flow at a known pressure.

Calculate volumetric efficiency using the formula in Section 7.

If efficiency is significantly below specification, suspect internal leakage.

6.5 Temperature and Noise Monitoring

Use an infrared thermometer to monitor casing temperature at multiple points.

Listen for cavitation noise: sharp crackling, rattling or gravel?like sounds.

Check for abnormal vibration using a simple vibration meter where available.

6.6 Suction Side Evaluation

Verify oil level in the reservoir and ensure the suction pipe inlet is submerged.

Clean or replace suction strainers and check for collapse or deformation.

Inspect suction hose for kinks, collapse under vacuum, or porous material.

Perform a vacuum test on the suction line to detect air ingress points.

6.7 System Valve and Relief Valve Checks

Confirm all manual valves are in the intended position (fully open or correctly throttled).

Check the relief valve setting using a calibrated gauge and adjust if necessary.

Inspect filter differential pressure indicators and bypass valves.

6.8 Internal Inspection

If external inspection, pressure tests, and flow tests indicate significant internal leakage, disassemble the

gear pump for internal inspection.

Mark the relative position of components before disassembly.

Check gear teeth for scoring, pitting, wear and deformation.

Measure side clearances and end float against design tolerances.

Inspect bushings, bearings and wear plates for uneven wear.

Look for cavitation erosion and corrosion on internal surfaces.

7. Key Measurements and Calculations for Troubleshooting

7.1 Volumetric Efficiency Calculation

Volumetric efficiency is a primary indicator of internal leakage in gear pumps. It can be calculated using:

η_v = Q_actual / Q_theoretical

Q_theoretical = Displacement (cm3/rev) × Speed (rev/min) ÷ 1000 (for L/min)

Q_actual = Flow measured at pump outlet at the test pressure.

7.2 Example Volumetric Efficiency Table

Operating Pressure (bar)	Theoretical Flow (L/min)	Measured Flow (L/min)	Calculated η_v (%)	Condition Assessment
50	60	57	95	Excellent – minimal internal leakage.
150	60	51	85	Acceptable for many applications.
200	60	42	70	Indicative of wear – consider overhaul.
250	60	33	55	Severe internal leakage – pump near end of life.

7.3 Pressure Drop Across Components

To localize system pressure drops, measure pressures at different points:

Location	Measured Pressure (bar)	Typical Pressure Drop (bar)	Diagnostic Interpretation
Pump discharge	P₁	Reference	Baseline for analyzing downstream losses.
After filter	P₂	P₁ - P₂	If > recommended value, filter may be clogged.
Downstream of valve	P₃	P₂ - P₃	Excessive drop indicates valve restriction or sizing problem.

8. Troubleshooting Tables for Leakages and Pressure Drops

8.1 Internal Leakage Troubleshooting Table

Symptom	Likely Cause	Corrective Action
Low system pressure, low volumetric efficiency, high oil temperature.	Worn gear teeth and housing clearances.	Inspect and measure internal components; repair or replace gears, wear plates, bushings as needed.
Pressure decays quickly under constant flow demand.	Distorted pump casing or cover causing uneven clearance.	Check flatness of mating surfaces; replace warped casings or covers; verify torque sequence during assembly.
Performance drops sharply at high temperature.	Fluid viscosity too low for operating temperature.	Select correct fluid viscosity grade; improve cooling; reduce operating temperature.
Gradual loss of pressure over long period of operation.	Progressive internal wear due to contamination.	Improve filtration; flush system; overhaul pump and replace worn components.

8.2 External Leakage Troubleshooting Table

Symptom	Likely Cause	Corrective Action
Oil leaking from shaft area.	Damaged or worn shaft seal; shaft run?out; incorrect seal material.	Verify shaft alignment and run?out; install new seal of correct material; check for overpressure at seal.
Oil seeping around housing joint or cover plate.	Damaged gasket, O?ring or insufficient bolt torque.	Replace gasket or O?ring with compatible material; torque bolts to specification in correct sequence.
Sudden high?rate leakage from body or ports.	Cracked housing or port block due to shock load.	Shut down immediately; replace housing; investigate root cause of mechanical or hydraulic shock.

8.3 Pressure Drop Troubleshooting Table

Symptom	Likely Cause	Corrective Action
System cannot build pressure beyond low level.	Relief valve set too low or stuck open.	Inspect and clean relief valve; verify setting; replace if seat is worn or damaged.
Pressure fluctuates and system is noisy.	Cavitation due to restricted suction line.	Increase suction line size; reduce suction lift; clean suction strainer; ensure proper reservoir design.
High pressure at pump discharge, low pressure at actuators.	Excessive pressure drop in piping, filters or valves.	Check and size piping correctly; replace clogged filters; adjust valve settings.
Low pressure, low flow, but pump draws normal power.	Severe internal leakage with no external fault.	Perform detailed internal inspection; recondition or replace pump.

9. Preventive Measures to Reduce Leakages and Pressure Drops

Preventing gear pump leakages and pressure drops is more cost?effective than corrective maintenance. The

following practices can significantly improve reliability.

9.1 Proper Pump Selection

Match displacement and pressure rating with system requirements.

Select appropriate pump type (external or internal gear) for the fluid and duty cycle.

Ensure compatibility of materials with the fluid (corrosion, swelling, chemical attack).

Consider viscosity range across full temperature envelope.

9.2 Fluid Selection and Cleanliness

Use a fluid with viscosity within the recommended range at operating temperature.

Maintain cleanliness level according to the most sensitive component in the system.

Install high?quality filters on pressure and return lines where applicable.

Regularly sample fluid for contamination, viscosity and degradation.

9.3 Suction Line Design

Use large?diameter suction piping with minimal bends and restrictions.

Keep suction piping as short as practical.

Place the pump as close to the reservoir as possible, preferably below fluid level.

Use appropriate strainers with low pressure drop and easy access for cleaning.

9.4 Operating Practices

Avoid running the pump dry during startup or after maintenance.

Warm up the system gradually in cold conditions to avoid thermal shock.

Avoid frequent cycling between zero and maximum pressure where possible.

Monitor pressure, temperature and noise regularly to catch early signs of problems.

9.5 Scheduled Maintenance

Establish inspection intervals based on operating hours and severity of service.

Check shaft seals, gaskets and connections for early signs of leakage.

Measure pump performance periodically using flow and pressure tests.

Plan pump overhaul or replacement before catastrophic failure occurs.

10. Typical Gear Pump Design Specifications (General Reference)

The following table provides typical general ranges for gear pump specifications. Actual ratings depend on

specific pump designs, materials, and manufacturers. Values serve as general guidelines for understanding

limits related to leakages and pressure drops.

Parameter	Typical Range	Impact on Leakages and Pressure Drops
Displacement	1 – 250 cm3/rev (small to medium industrial pumps)	Determines theoretical flow; used to calculate volumetric efficiency and detect internal leakage.
Maximum continuous pressure	80 – 250 bar (hydraulic); lower for light?duty or lubrication pumps	Operation above rated pressure accelerates wear and internal leakage.
Speed range	500 – 3500 rpm (application?dependent)	Higher speeds increase risk of cavitation and suction?side pressure drops.
Recommended viscosity	10 – 300 cSt at operating temperature	Too low viscosity increases internal leakage; too high viscosity raises suction losses.
Fluid temperature range	-20 °C to +80 °C (standard designs)	Extreme temperatures affect fluid viscosity and seal life, influencing leakages.
Suction pressure limits	Typically -0.3 to +0.5 bar gauge	Excessive vacuum leads to cavitation and internal damage.

11. Best Practices for Gear Pump Troubleshooting

11.1 Establish Baseline Data

Record initial flow, pressure and temperature data when the system is new.

Keep documentation of all settings: relief valve, fluid type, filter specifications.

11.2 Use Systematic Diagnostic Methods

Always start with the simplest checks: fluid level, valves, filters.

Separate pump issues from system issues using by?pass or test circuits when possible.

Use temporary test equipment such as portable flow meters and digital pressure gauges.

11.3 Focus on Root Causes, Not Just Symptoms

If a shaft seal fails repeatedly, investigate misalignment or pressure spikes.

If internal leakage increases quickly, examine filtration and fluid contamination.

If cavitation is frequent, redesign the suction line rather than just replacing pumps.

11.4 Documentation and Continuous Improvement

Document all troubleshooting steps and outcomes.

Use failure data to refine maintenance schedules and design improvements.

Train operators to recognize early warning signs of leakages and pressure drops.

12. Frequently Asked Questions about Gear Pump Leakages and Pressure Drops

12.1 How do I know if my gear pump has internal leakage?

Internal leakage is suspected when the pump cannot reach expected pressure even though the drive power is

available and no external leak is visible. Confirm by measuring actual flow and comparing it with theoretical

flow to calculate volumetric efficiency. A significant drop in efficiency, especially at higher pressures,

indicates internal leakage.

12.2 Can low viscosity cause both leakages and pressure drops?

Yes. Low viscosity reduces the fluid’s ability to seal internal clearances, which increases internal leakage

and reduces volumetric efficiency. At the same time, low viscosity can reduce frictional losses in the

system, but the dominant effect in gear pumps is usually reduced capacity to build and maintain pressure.

12.3 What is the difference between cavitation and aeration, and how do they affect pressure?

Cavitation is the formation and collapse of vapor bubbles due to local pressure dropping below fluid vapor

pressure. Aeration is the presence of entrained air bubbles from external sources. Both decrease effective

fluid density and compressibility, disrupt flow continuity, and damage pump surfaces. This leads to pressure

instability, noise, and progressive efficiency loss.

12.4 When should a gear pump be repaired instead of replaced?

Gear pump repair is usually justified when the casing, shafts and major components are structurally sound and

only wear parts such as gears, bushings, seals and plates are affected. When volumetric efficiency drops

below an acceptable threshold and internal wear is extensive, replacement may be more cost?effective.

13. Conclusion

Reliable gear pump operation depends on controlling leakages and minimizing unwanted pressure drops. By

understanding the mechanisms of internal and external leakage, recognizing early warning symptoms, and

following a structured troubleshooting procedure, maintenance teams can extend pump life, improve system

efficiency, and avoid unplanned downtime. Applying best practices in pump selection, fluid management,

suction line design and preventive maintenance will reduce the frequency and severity of gear pump

problems related to leakages and pressure drops across a wide range of industrial applications.

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