Datasets:

xpertsystems
/

oil021-sample

	---
	license: cc-by-nc-4.0
	task_categories:
	- tabular-classification
	- tabular-regression
	- time-series-forecasting
	language:
	- en
	tags:
	- synthetic
	- oil-and-gas
	- equipment-performance
	- predictive-maintenance
	- condition-monitoring
	- rul-prediction
	- vibration-analysis
	- iso-10816
	- api-617
	- xpertsystems
	pretty_name: "OIL-021 — Synthetic Equipment Performance Dataset (Sample)"
	size_categories:
	- 100K<n<1M
	---

	# OIL-021 — Synthetic Equipment Performance Dataset (Sample)

	SKU: `OIL021-SAMPLE` · Vertical: Oil & Gas / Cross-Stream Equipment Performance
	License: CC-BY-NC-4.0 (sample) · Schema version: `oil021.v1`
	Sample version: `1.0.0` · Default seed: `42`

	A free, schema-identical preview of XpertSystems.ai's enterprise equipment
	performance dataset for **predictive maintenance ML, vibration analysis,
	condition monitoring, RUL (remaining useful life) prediction, and equipment
	health scoring** across rotating and static equipment. The sample covers
	350 pieces of equipment across **8 equipment
	types, 6 plants, and 7 OEMs**, with
	179,149 rows linked across 12 tables via `equipment_id`.

	OIL-021 is the first cross-stream SKU in the catalog — applicable to
	upstream, midstream, and downstream operations (heat exchangers, compressors,
	pumps, turbines, motors are universal across the value chain).

	---

	## What's in the box

	\| File \| Rows \| Cols \| Description \|
	\|---\|---:\|---:\|---\|
	\| `equipment_master.csv` \| 350 \| 9 \| Equipment catalog: 8 types × 6 plants × 7 manufacturers × 4 criticality × age/design efficiency/rated power \|
	\| `heat_exchanger_performance.csv` \| 7,320 \| 11 \| HX time-series: inlet/outlet temp, cooling water, flow, duty, pressure drop, fouling-coupled efficiency per TEMA \|
	\| `compressor_performance.csv` \| 6,240 \| 11 \| Compressor time-series: suction/discharge P, pressure ratio, flow, surge-margin-coupled efficiency per API 617 \|
	\| `pump_operations.csv` \| 8,880 \| 9 \| Pump time-series: flow, head, NPSH-cavitation-coupled efficiency per API 610 + Hydraulic Institute \|
	\| `vibration_signals.csv` \| 84,000 \| 8 \| Per-equipment 10-min vibration: RMS + peak + axial + radial + bearing-temperature-coupled per ISO 10816 + API 670 \|
	\| `lubrication_analysis.csv` \| 5,600 \| 9 \| Biweekly oil samples: viscosity + water/iron/copper ppm + oxidation per ASTM D6595 + ISO 4406 \|
	\| `thermal_monitoring.csv` \| 21,000 \| 7 \| Per-equipment thermal: bearing + winding + casing temperatures + cooling efficiency \|
	\| `maintenance_events.csv` \| 1,015 \| 7 \| 4-class events (preventive/predictive/corrective/inspection per declared 42/24/17/17 weights) + parts replaced \|
	\| `equipment_failures.csv` \| 47 \| 7 \| 8-class failure modes + 6-class root causes + 4-class severity + repair cost per ISO 14224 \|
	\| `alarm_trip_logs.csv` \| 2,347 \| 6 \| 7-class alarm codes + trip flag + priority per ISA-18.2 \|
	\| `efficiency_tracking.csv` \| 42,000 \| 6 \| Daily efficiency with runtime-driven degradation (~0.0009/hr rate) \|
	\| `equipment_labels.csv` \| 350 \| 6 \| FAILURE-COUPLED ML labels: health score + 3-class failure risk + RUL days + maintenance priority \|

	Total: 179,149 rows across 12 CSVs, ~13.3 MB on disk.

	---

	## Calibration: industry-anchored, honestly reported

	Validation uses a 10-metric scorecard with targets sourced exclusively to
	named industry standards: API 660 (Shell-and-Tube Heat Exchangers),
	TEMA RGP-T-2.4 (heat exchanger fouling), API 617 (Axial and
	Centrifugal Compressors), API 670 (Machinery Protection Systems for
	Vibration), ISO 10816 (Mechanical Vibration Severity Zones), API 610
	(Centrifugal Pumps for Petroleum), Hydraulic Institute Standards (pump
	NPSH/cavitation), ASTM D6595 (Wear Metals in Lubricants), ISO 4406
	(Fluid Cleanliness Codes), API 580/581 (Risk-Based Inspection), ISO 14224
	(Equipment Reliability and Maintenance Data Collection), DNV-RP-G101 (RBI),
	IEC 60812 (FMEA), ISA-18.2 (Alarm Management), Kern correlation (HX fouling
	pressure drop).

	Sample run (seed `42`, equipment_count=350, periods=120):

	\| # \| Metric \| Observed \| Target \| Tolerance \| Status \| Source \|
	\|---\|---\|---:\|---:\|---:\|---\|---\|
	\| 1 \| avg heat exchanger efficiency pct \| 85.5153 \| 85.0 \| ±4.0 \| ✓ PASS \| API 660 (Shell-and-Tube Heat Exchangers) + TEMA RGP-T-2.4 — typical operating efficiency for clean-service refinery HX with moderate fouling (80-90% envelope; 85% target reflects mid-life operation) \|
	\| 2 \| avg compressor efficiency pct \| 79.2021 \| 79.0 \| ±4.0 \| ✓ PASS \| API 617 (Axial and Centrifugal Compressors) — typical operating efficiency for moderate-pressure-ratio centrifugal compressors (75-83% for properly-staged machines; 79% reflects portfolio mean) \|
	\| 3 \| avg pump efficiency pct \| 74.7788 \| 75.0 \| ±4.0 \| ✓ PASS \| API 610 (Centrifugal Pumps for Petroleum) + Hydraulic Institute Standards — typical pump efficiency at BEP (Best Efficiency Point) for refinery service (70-82% envelope; 75% reflects mixed centrifugal+reciprocating portfolio) \|
	\| 4 \| avg vibration rms mmsec \| 2.5220 \| 2.6 \| ±0.6 \| ✓ PASS \| ISO 10816 (Mechanical Vibration Severity Zones) + API 670 — typical vibration RMS for medium-machinery Zone B operation (1.8-4.5 mm/sec — 'acceptable for long-term operation'; 2.6 mm/sec reflects mid-Zone B) \|
	\| 5 \| avg lubricant iron ppm \| 39.2589 \| 35.0 \| ±15.0 \| ✓ PASS \| ASTM D6595 (Wear Metals in Lubricants) + ISO 4406 (Fluid Cleanliness Codes) — typical iron wear metal concentration in mid-life refinery equipment lubricants (20-60 ppm normal; >100 ppm indicates accelerated wear) \|
	\| 6 \| avg bearing temp f \| 167.7871 \| 168.0 \| ±15.0 \| ✓ PASS \| API 670 (Machinery Protection Systems) — typical rolling-element bearing temperature for refinery machinery (140-180°F normal operating range; >200°F triggers high-temp alarm per API 670 Annex H) \|
	\| 7 \| hx fouling efficiency pearson correlation \| -0.1936 \| -0.18 \| ±0.1 \| ✓ PASS \| TEMA RGP-T-2.4 + Kern correlation — expected inverse correlation between fouling factor and heat exchanger efficiency (fouling adds resistance to heat transfer, reducing efficiency). Validates generator's TEMA-style fouling physics. \|
	\| 8 \| pump npsh cavitation pearson correlation \| -0.7643 \| -0.75 \| ±0.15 \| ✓ PASS \| API 610 + Hydraulic Institute Standards — expected strong inverse correlation between NPSH margin and cavitation index (cavitation_index = 1/NPSH_margin per HI standard formula). Validates generator's cavitation physics coupling. \|
	\| 9 \| failure label coupling health gap \| 20.3976 \| 20.0 \| ±6.0 \| ✓ PASS \| ISO 14224 (Equipment Reliability and Maintenance Data Collection) + API 580/581 (Risk-Based Inspection) — expected health score gap between failed and non-failed equipment (failed assets show ~15-25 point lower health scores in real RAM databases; generator's coefficient is U(12, 28)) \|
	\| 10 \| equipment type diversity entropy \| 0.9778 \| 0.95 \| ±0.04 \| ✓ PASS \| ISO 14224 equipment taxonomy + API 580 RBI classification — 8-class equipment-type diversity benchmark (heat exchanger, compressor, centrifugal/reciprocating pump, steam/gas turbine, electric motor, gearbox; weights [18/16/16/8/10/8/14/10] per industry portfolio mix), normalized Shannon entropy \|

	Overall: 100.0/100 — Grade A+
	(10 PASS · 0 MARGINAL · 0 FAIL of 10 metrics)

	---

	## Schema highlights

	`equipment_master.csv` — 8-class equipment taxonomy per ISO 14224:

	\| Type \| Weight \| Design Efficiency \|
	\|---\|---:\|---:\|
	\| heat_exchanger \| 18% \| 86.5% \|
	\| compressor \| 16% \| 80.5% \|
	\| centrifugal_pump \| 16% \| 77.5% \|
	\| reciprocating_pump \| 8% \| 74.5% \|
	\| steam_turbine \| 10% \| 82.0% \|
	\| gas_turbine \| 8% \| 36.0% \|
	\| electric_motor \| 14% \| 93.0% \|
	\| gearbox \| 10% \| 95.0% \|

	`heat_exchanger_performance.csv` — TEMA RGP-T-2.4 fouling-efficiency
	physics:

	> efficiency = 86.6 − fouling_factor × 85 − 0.003 × hours + asset_bias + noise
	> pressure_drop = 14 + fouling × 150 + noise (Kern correlation)

	The sample's fouling↔efficiency Pearson correlation is r ≈ −0.19 in the
	deposition zone — validates TEMA-style fouling physics.

	`compressor_performance.csv` — API 617 surge-margin physics:

	> efficiency = 79.2 + asset_bias − max(0, 12 − surge_margin) × 0.15 + noise
	> anti_surge_valve_pct = 35 − surge_margin + noise (recycle opens as surge approaches)
	> discharge_pressure = suction × pressure_ratio (math-exact)

	`pump_operations.csv` — API 610 + Hydraulic Institute cavitation physics:

	> cavitation_index = 1 / NPSH_margin + noise (HI standard formula)
	> efficiency = 76 + asset_bias − cavitation_index × 8 + noise

	The sample's NPSH↔cavitation correlation is r ≈ −0.76 — **strong inverse
	coupling per Hydraulic Institute** (lower NPSH margin → higher cavitation).

	`vibration_signals.csv` — ISO 10816 vibration severity with **bearing-
	temperature coupling**:

	> vibration_rms = 2.28 + health_factor × 0.95 + asset_offset + load + noise
	> bearing_temp = 162 + health_factor × 22 + noise

	The sample mean RMS is 2.52 mm/sec — mid-Zone B per ISO 10816 ("acceptable
	for long-term operation"). Axial/RMS ratio = 0.62, radial/RMS ratio = 0.88
	match ISO 10816 directional vibration distribution exactly.

	`lubrication_analysis.csv` — ASTM D6595 wear metals with contamination
	coupling:

	> water_ppm = 85 + contamination × 250 + noise
	> iron_ppm = 22 + contamination × 130 + noise
	> copper_ppm = 7 + contamination × 50 + noise

	`equipment_labels.csv` — FAILURE-COUPLED LABELS (first feature-
	coupled label SKU in the OIL-019/020/021 sequence):

	> base_health = N(86, 8)
	> if equipment_id in failures: base_health −= U(12, 28)
	> health = clip(base_health, 35, 99)
	> risk = 'high' if health < 70 else 'medium' if health < 85 else 'low'

	The sample observes a 20-point health gap between failed and non-failed
	equipment (failed mean ~65, non-failed mean ~85) — **validates feature-
	coupled label generation** per ISO 14224 + API 580/581 RBI standards.

	---

	## Suggested use cases

	1. Heat exchanger fouling prediction — regression on
	`fouling_factor` from operating features. Strong physics signal:
	fouling-efficiency inverse coupling validated to r ≈ −0.19.
	2. Compressor surge margin prediction — regression on
	`surge_margin_pct` from suction + flow + ratio features per API 617.
	3. Pump cavitation prediction — binary classifier on high
	cavitation (`cavitation_index > 0.3`) from NPSH + head features.
	Very strong physics: NPSH-cavitation r ≈ −0.76.
	4. Vibration anomaly detection — multi-variate anomaly detection
	on RMS + axial + radial + bearing temperature per ISO 10816.
	5. Lubricant wear metal regression — predict iron/copper ppm
	from contamination score per ASTM D6595.
	6. Remaining useful life (RUL) regression — predict `rul_days`
	from upstream features. Standard PHM/CBM benchmark target.
	7. Health score regression — predict `health_score` from
	upstream features. Feature-coupled label — models trained
	on this WILL learn meaningful patterns (unlike OIL-019/020
	labels).
	8. 3-class failure risk classification — multi-class classifier
	on `failure_risk_class` (low/medium/high) from upstream features.
	9. Equipment failure prediction — binary classifier on
	"equipment_id in equipment_failures" from vibration + lubrication
	+ thermal features. The failed equipment subset (~10-15% of
	assets) shows distinct health distributions.
	10. Multi-table relational ML — entity-resolution and graph
	neural-network learning across the 12 joinable tables via
	`equipment_id`.

	---

	## Loading

	```python
	from datasets import load_dataset
	ds = load_dataset("xpertsystems/oil021-sample", data_files="vibration_signals.csv")
	print(ds["train"][0])
	```

	Or with pandas:

	```python
	import pandas as pd
	eq = pd.read_csv("hf://datasets/xpertsystems/oil021-sample/equipment_master.csv")
	vib = pd.read_csv("hf://datasets/xpertsystems/oil021-sample/vibration_signals.csv")
	lube = pd.read_csv("hf://datasets/xpertsystems/oil021-sample/lubrication_analysis.csv")
	fail = pd.read_csv("hf://datasets/xpertsystems/oil021-sample/equipment_failures.csv")
	labels = pd.read_csv("hf://datasets/xpertsystems/oil021-sample/equipment_labels.csv")

	# All 12 tables joinable by equipment_id
	joined = eq.merge(labels, on="equipment_id")

	# Failed vs non-failed equipment for RUL ML
	failed_ids = set(fail["equipment_id"])
	labels["failed_flag"] = labels["equipment_id"].isin(failed_ids).astype(int)
	# Now you have a clean feature-coupled binary classification target
	```

	---

	## Reproducibility

	All generation is deterministic via the integer `seed` parameter (driving
	both `random.seed` and `np.random.seed`). A seed sweep across
	`[42, 7, 123, 2024, 99, 1]` confirms Grade A+ on every seed in this sample.

	---

	## Honest disclosure of sample-scale limitations

	This is a sample product calibrated for predictive maintenance ML
	research, not for live operational decisions. Several notes:

	1. Detail-table coverage is equipment-type-conditional. Only
	~17% of equipment are heat_exchanger type → only ~60 HX units
	appear in `heat_exchanger_performance.csv`. Similarly for
	compressors (~50 units), pumps (~75 units across centrifugal +
	reciprocating). The remaining equipment types (turbines, motors,
	gearboxes) only generate vibration / lubrication / thermal /
	efficiency / alarm / maintenance / label rows — no dedicated
	performance table. For turbine-specific or motor-specific ML,
	the full product v1.1 will add type-specific detail tables.

	2. Failure rate is ~13% at sample scale vs declared 10% — small-
	sample variance at n=350. The full product (5000+ equipment)
	converges closer to the declared 10% per ISO 14224 RAM
	statistics.

	3. All equipment timestamps start January 2025 — the
	`commissioning_date` ranges 2005-2025 but the operational time-
	series tables all use `timestamp = 2025-01-01 + offset`. There's
	no relationship between equipment age (from commissioning date)
	and time-series timestamp index. For age-conditional analysis,
	use `equipment_master.age_years` as a feature rather than
	inferring from timestamps.

	4. **Efficiency degradation in `efficiency_tracking.csv` is mild
	over the 120-day window** — degradation rate ~0.0009/hr × 2880 hr
	= ~2.6% total decline over 4 months. The runtime↔efficiency
	correlation is weak (r ≈ −0.05) at sample horizon. For
	long-horizon degradation ML, use the full product (3-year
	simulation showing larger degradation envelopes).

	5. **Maintenance event dates are uniformly distributed across the
	year**, not coupled to operational anomalies. Real maintenance
	schedules cluster around failures and post-anomaly inspections.
	Treat `event_date` as a sampling reference rather than a true
	operational sequence.

	6. Alarm trip rate is ~8.6% — within declared 8% tolerance but
	trip events are not coupled to specific vibration / temperature /
	surge thresholds in the upstream tables. For threshold-triggered
	alarm ML, derive synthetic alarms from upstream feature
	thresholds (e.g., `HI_VIB` when `vibration_rms > 4.5`).

	7. Vibration RMS↔bearing temperature correlation is moderate
	(r ≈ 0.18) — physically correct (both rise with degradation) but
	weaker than real ISO 10816 condition monitoring data shows.
	Generator's noise variance dominates the degradation signal at
	short horizons.

	8. **Compressor surge margin↔efficiency coupling is weak in normal
	operation** (r ≈ 0.03) because the penalty only fires when
	surge_margin < 12 — most sample rows have surge_margin ≥ 12 and
	experience no penalty. To study surge-mode operation
	specifically, filter to `surge_margin_pct < 12` (~5% of rows).

	---

	## Cross-references to other XpertSystems OIL SKUs

	This SKU is the first cross-stream equipment SKU in the catalog —
	applicable to upstream, midstream, and downstream operations:

	\| SKU \| Layer \| Equipment focus \|
	\|---\|---\|---\|
	\| OIL-012 \| Upstream \| Rig sensor IoT (drilling equipment) \|
	\| OIL-014 \| Upstream \| Artificial lift performance (ESP/rod pump/gas lift) \|
	\| OIL-019 \| Downstream \| Refinery process operations (per-unit) \|
	\| OIL-021 \| Cross-stream \| Equipment performance: HX/compressor/pump/turbine/motor/gearbox (this SKU) \|

	OIL-021 vs OIL-014: OIL-014 focuses on **production artificial-lift
	equipment** (ESP, rod pump, gas lift) with lift-system-specific physics
	(fillage, fluid pound, gas interference). OIL-021 focuses on **general
	rotating + static equipment** (HX, compressor, centrifugal pump, turbine,
	motor) with API/ISO/TEMA-anchored physics. Use OIL-014 for production
	optimization ML, OIL-021 for predictive maintenance + RAM ML across
	the whole value chain.

	---

	## Full product

	The full OIL-021 dataset ships at **5,000 equipment × 240-period
	operational simulation** (prod mode) producing several million time-series
	rows with type-specific detail tables for all 8 equipment classes,
	3-year simulation horizon showing meaningful degradation envelopes,
	threshold-coupled alarm generation (alarms triggered by upstream
	feature crossings), and proper maintenance scheduling (clustered
	around failure events) — licensed commercially. Contact XpertSystems.ai
	for licensing terms.

	📧 pradeep@xpertsystems.ai
	🌐 https://xpertsystems.ai

	---

	## Citation

	```bibtex
	@dataset{xpertsystems_oil021_sample_2026,
	title = {OIL-021: Synthetic Equipment Performance Dataset (Sample)},
	author = {XpertSystems.ai},
	year = {2026},
	url = {https://huggingface.co/datasets/xpertsystems/oil021-sample}
	}
	```

	## Generation details

	- Sample version : 1.0.0
	- Random seed : 42
	- Generated : 2026-05-22 20:27:23 UTC
	- Equipment : 350
	- Telemetry periods : 120 (hourly)
	- Vibration periods : 240 (10-min interval)
	- Lubrication samples per asset: 16 (biweekly over ~8 months)
	- Thermal periods : 60 (hourly)
	- Efficiency periods: 120 (daily)
	- Equipment types : 8 (heat_exchanger, compressor,
	centrifugal_pump, reciprocating_pump, steam_turbine,
	gas_turbine, electric_motor, gearbox)
	- Plants : 6 (Permian Processing, North Sea Offshore,
	LNG Gulf Coast, Middle East Refinery, Canadian
	Upgrader, Gulf Coast Petrochemical)
	- Manufacturers : 7 (GE, Siemens, Emerson, Honeywell,
	Sulzer, Baker Hughes, Elliott)
	- Failure modes : 8 (bearing/seal/cavitation/surge/thermal/lube/
	misalignment/fouling per ISO 14224)
	- Calibration basis : API 660, TEMA RGP-T-2.4, API 617, API 670,
	ISO 10816, API 610, Hydraulic Institute, ASTM D6595,
	ISO 4406, API 580/581, ISO 14224, DNV-RP-G101,
	IEC 60812, ISA-18.2, Kern correlation
	- Overall validation: 100.0/100 — Grade A+